DE3309404C2 - - Google Patents

Description

The invention relates to a method for determining the Mass flow rate of a flowing medium according to the preamble of the patent entit 1 or of a device for performing a such a method according to the preamble of claim 5.

Such a process and such a device are from the DE 20 42 983 B2 known. The device described there is the task on the basis of a fuel injection system for an internal combustion engine to achieve that sucked in by the internal combustion engine Airflow very accurate with rapid changes in airflow can be measured practically without delay and an exact, for the clean combustion enables the required fuel metering becomes. To solve this problem, a device is proposed where two temperature dependent resistors in different Branches of a measuring bridge are arranged. The bridge is like that dimensioned that due to a temperature-dependent resistance of the great current flowing through it  to a high, above the temperature value of the flowing medium heated temperature value becomes. The second temperature-dependent resistor is used to compensate for the influence of the fluctuating temperature of the flowing medium. The one through the bridge flowing electricity is with the help of a control device regulated in such a way that the heated temperature-dependent Resistance a constant temperature difference with respect to the intake air temperature. As Measure of the flow past this resistance per unit of time Air mass can e.g. B. by the bridge flowing electricity can be used. Approximately results that the bridge current is proportional to the fourth Is the root of the air mass flow.

Although this arrangement is in the range of high air mass flow rates works satisfactorily Range of small air mass flow rates an increase in sensitivity or resolution this known device. The reason for this is in the fact that the one determined in the experiment Relationship between mass flow and bridge current deviates from the theoretical context mentioned above. For an air mass flow of zero or the bridge current does not take very small values the value zero, but is approximately a quarter of the maximum bridge current. Because of this experimental There is a significant narrowing of the relationship exploitable measuring range of the bridge current, the especially in the case of small air mass flow rates Connection with the present large gradient the characteristic curve has a negative effect on the measurement error.  

Furthermore, for example from "hot wire and Hot film anemometry ", H. Strickert, VEB Verlag Technik Berlin, 1974, another basic circuit of the hot wire Measuring technology known in which the resistance bridge is flowed through by a constant current. Like the comparison between on page 68 ff constant current operation and constant temperature Operation of the measuring bridge shows is in relation to the Absolute sensitivity below which the differential quotient from the bridge output voltage and air mass flow rate is to understand constant temperature operation to constant Electricity operation in the entire air mass flow rate range think. However, this statement does not apply to the relative Sensitivity of both methods, under which the differential quotient from bridge output voltage and air mass flow, related to the bridge output voltage, is to be understood. It turns out that this is relative Sensitivity for constant temperature operation only larger above a certain air mass flow rate Assumes values as for constant current operation. Below this threshold, however, turns out to be relative Sensitivity of constant current operation as superior.  

From DE-OS 16 98 050 is a device for measurement weak gas flows known in the way of gas flows and perpendicular to it at least two preferably flat metal grids are arranged, which form branches of a bridge circuit in which the grids of a constant lying in a bridge diagonal power source to a temperature above the ambient temperature are heated, in which the grid at such a distance are arranged from each other that there is heat coupling, and at measured in the other bridge diagonal in a manner known per se display or processing devices are arranged, in which in the other branches of the bridge circuit constant resistors (K₁ and K₂) are arranged, which are designed such that the Sensitivity (E) of the bridge circuit in a wider range is almost independent of the ambient temperature (T₁ or T₂).

Finally, DE 30 34 936 A1 describes a flow measuring device with at least one within which a medium flows Channel arranged hot wire known in which at one in one Channel arranged perpendicular to the direction of flow of the medium Vortex generators in the direction and symmetrical to the longitudinal direction of the Vortex generator and in the flowing medium a pair of hot wires are excited, so powered by a measuring circuit be heated to a fixed constant temperature and in which the measuring circuit is one that flows through the hot wires electric current regulating current control circuit, the when the hot wire resistance drops due to wire temperature lowering the current flowing through the hot wires, one first detection circuit, which consists of a resistance difference the repetition frequency of the generated vortices between the hot wires determined and a pulse signal corresponding to this frequency generates a second detection circuit, which from the through cut resistance of the hot wires an average flow speed of the medium determined and a corresponding  Analog signal generated, a sensing device for detecting a Flow state and to give a signal when the medium flows pulsatingly, and a switching stage that due to the signal the sensing device the analog signal, otherwise the pulse signal directs, includes.

The invention has for its object the above Method and the device mentioned above to improve so that both at high and at low air mass flow rates a measurement of the mass flow rate with high sensitivity and resolution.

The solution to this problem is through the in the characterizing part of the claims Measures 1 and 5 given.

The inventive method for determining the mass flow rate of a flowing medium according to claim 1 and the device for Carrying out the method for determining the mass throughput a flowing medium according to claim 5  to have compared to the prior art mentioned the advantage that by switching the Control device with small mass flow rates of Constant temperature control on constant current control the disadvantages mentioned known devices can be avoided. Doing so the switching point preferably in such a range in which the relative sensitivity of the constant Current operation of the constant temperature operation is superior. This measure is connected with a subtraction step an extension of the measuring range that characterize the air mass signal Voltage down to bridge output voltages of approx. 0 volts possible and thus an increased resolution is guaranteed.

The fact that that the decoupling depends on the air mass flow Measuring voltage in a uniform form for both Operating modes of the bridge is made.

Further advantages of the invention result from the listed in the subclaims and subsidiary claims Measures and from the description below the drawing.

Embodiments of the device are in the drawing shown and in the description below  explained in more detail. It shows

Fig. 1 shows an embodiment of the device according to the invention and

Fig. 2 shows a comparison of the characteristic curve of a prior art device and the device for determining the mass flow rate of a flowing medium according to the patent claim 5.

The bridge circuit of the embodiment of FIG. 1 comprises the resistors 10, 11, 12 and 13 , the two bridge branches each containing the resistors 10, 11 and 12, 13 as a series circuit. The base point of the two bridge branches as the connection point of the resistors 11 and 13 is at ground potential, while the other connection point 14 between the resistors 10 and 12 of the two bridge branches is connected to the emitter of an NPN transistor 15 . The bridge diagonal voltage is tapped between the points 16 and 17 as connection points of the resistors 12 and 13 or 10 and 11 and the inputs of a control amplifier 18 , which is embodied in the present exemplary embodiment as an operational amplifier with an open collector output. The output of the control amplifier 18 is connected via a resistor 19 to the base of the transistor 15 and via a resistor 20 to the supply voltage. The emitter of transistor 15 is connected to the inverting input of a comparison device 21 , which is also of the open collector type, and via a resistor 22 to the supply voltage. The non-inverting input of the comparison device 21 is acted upon by a reference voltage 23 related to the supply voltage and the output signal of this comparison device 21 is fed to the base of the transistor 15 .

A subtraction stage 24 is connected to the bridge diagonal points 16 and 17 , the output signal of which represents the measured value for the mass flow rate of the flowing medium. This subtracter 24 includes in known manner a differential amplifier 25 whose negative input is connected via a resistor 26 to the bridge diagonal point 16 and via a resistor 27 to the output in combination. The plus input of the differential amplifier 21 is connected to the bridge diagonal point 17 .

This device works as follows. Starting from the high mass flow rates of the flowing medium, in which the means in the constant-temperature working operation, the voltage drop 10 required current I _H exceeds the resistor 22 due to the high, to maintain the temperature of the measuring resistor the value of the reference voltage source 23rd Due to the design of the comparison device 21 as an open collector type, the output of which is blocked for positive input voltage differences (U ₊ -U _- ), this comparison device 21 has no influence on the voltage at the base of the transistor 15 for high mass throughputs. This voltage is then determined solely by the output signal of the control amplifier 18 , in such a way that the bridge diagonal voltage between points 16 and 17 becomes identical to zero.

If, on the other hand, the mass flow rate of the flowing medium assumes such small values that the voltage drop caused by the bridge current I _H across the resistor 22 assumes smaller values than the reference voltage 23 , the output of the comparison device 21 is switched to low resistance and the base of the transistor 15 is supplied with a voltage driven so that a constant current given by the ratio of the reference voltage and the resistance value of the resistor 22 flows through the bridge. This bridge current, which essentially flows through the right bridge branch with the resistors 10, 11 , causes a constant voltage drop U 1 at the resistor 11 , which is present at the minus input of the control amplifier 18 . As the mass flow rate decreases, the amount of heat withdrawn from the measuring resistor 10 simultaneously decreases, so that the latter heats up. This results in a temperature increase in the resistor 10 , which in turn has a voltage rise at the collector of the transistor 14 . This voltage rise at point 14 is the voltage divider ratio of resistors 12 and 13 corresponding to point 16 , the positive input of the control amplifier 18 , transmitted. As soon as U ₊ (point 16 ) assumes larger values than U _- (point 17 ), the output of the control amplifier 18 is switched to the blocking state. When a threshold value given by the resistor 22 and the reference voltage 23 is reached, an automatic switchover occurs, so that the base of the transistor 15 is controlled either by the output of the comparison device 21 or by the output of the control amplifier 18 .

The output variable at the output of the subtraction stage 24 , which is dependent on the mass flow rate of the flowing medium, results for the two control modes in the following way:

In the case of constant temperature operation, the diagonal voltage of the bridge between points 16 and 17 assumes the value zero in the steady state, so that the voltage drop across resistors 11 and 13 is the same. According to the mode of operation of a negative feedback differential amplifier, the output voltage is set in its linear working range in such a way that the voltage difference at the inputs (minus and plus) becomes identical to zero. As a result of the only common mode control of the differential amplifier 25 , this immediately results in the output voltage U _A taking on exactly the value of the voltage drop across the resistor 11 which is normally used as an output variable in constant-temperature operation.

If the device switches from constant temperature operation to constant current operation, this operating mode results in a bridge imbalance, ie the bridge diagonal voltage between points 16 and 17 takes on values not equal to zero. Due to its wiring, the differential amplifier 25 then works as a subtracting stage and the output voltage results in:

U _A = U₁₁ + R₂₇ / R₂₆ · (U₁₁-U₁₃),

the numbers given refer to the voltage drops or resistance values of the correspondingly labeled resistors. By a suitable choice of the resistance ratio of the resistors R₂₇ and R₂₆, the output voltage can be set in such a way that the output voltage U _A assumes the value zero at a mass flow of zero.

Fig. 2 shows a diagram in which the output voltage U _A is plotted against the mass flow rate Q _m . The dashed line shows the characteristic curve II of known devices which are regulated over the entire mass throughput range in constant temperature operation. Even for mass flow rates in the range of zero, the output voltage takes on quite high values, so that the usable measuring range U _A is narrowed by approx. 25% to 30%. The second curve I drawn in solid lines represents the behavior of a device controlled in constant current mode. By a suitable resistance selection of the resistors R₂₇ and R₂₆ can be achieved in this case that the output voltage U _A for Q _m = 0 assumes the value U _A = 0. The available measuring range can be expanded considerably by this operating mode, just as the sensitivity is increased due to the larger differential quotient of the characteristic curve for small mass flow rates. The switchover point U _{A, S} , which corresponds to a mass flow rate Q _{m, S} between these two operating modes, can be set independently by a suitable choice of the resistor 22 and the reference voltage 23 .

This device results from the larger, usable measuring range an increased Sensitivity in mass flow rate determination as well a greater relative sensitivity especially for small mass flow rates. In addition, the  Diversity of the two standard operations one degree of freedom obtained for setting the parameters.

It is understood that the process as well not only the device for performing the method for bridge circuits in the conventional sense, as in Embodiment are shown, but also for such circuit arrangements, at least by the function a bridge circuit as a resistance measuring arrangement replicate, is used.

Claims (9)

1. A method for determining the mass flow rate of a flowing medium, in particular the air mass flow rate, which is required by an internal combustion engine during the combustion process, with a circuit arrangement operating as a resistance measuring arrangement in the manner of a bridge circuit with at least one temperature-dependent resistor exposed to the flowing medium and a control device for regulation of the current flowing through the temperature-dependent resistance, characterized in that the mass flow rate of the flowing medium is determined by switching the control below a selectable threshold value in constant current mode and above the threshold value in constant temperature mode. 2. The method according to claim 1, characterized in that the Threshold for switching the control from constant temperature Operation on constant current operation in the range of such mass flow rates of the flowing medium, in which the relative sensitivity a constant current control that a constant temperature control surpasses. 3. The method according to claim 1 or 2, characterized in that the switching process from constant temperature operation to constant current operation is carried out with the aid of a comparison device ( 21 ) which is in relation to an adjustable to the total current flowing through the bridge Reference value is sensitive. 4. The method according to any one of the preceding claims, characterized in that the output signal of a subtracting stage ( 24 ) is used to determine the mass flow rate of the flowing medium, the inputs of which are connected to the bridge diagonal points ( 16, 17 ). 5. Apparatus for carrying out the method for determining the mass flow rate of a flowing medium, in particular the air mass flow rate, which is required by an internal combustion engine during the combustion process, with a circuit arrangement operating as a resistance measuring arrangement in the manner of a bridge circuit with at least one temperature-dependent, exposed to the flowing medium Resistor and a regulating device for regulating the current flowing through the temperature-dependent resistor according to one of claims 1 to 4, characterized in that the base of a transistor ( 15 ) controlling the bridge current in the case of constant current operation with the output signal of a comparison device ( 21 ) is applied, the inputs of which are fed a signal proportional to the bridge current and a constant reference value. 6. The device according to claim 5, characterized in that the base of the transistor ( 15 ) controlling the bridge current after switching from constant current operation to constant temperature operation with the output signal of a control amplifier connected to the bridge diagonal points ( 16, 17 ) ( 18 ) is applied. 7. The device according to claim 6, characterized in that the control amplifier ( 18 ) and the comparison device ( 21 ) have open-collector outputs which for an input voltage difference (U ₊ -U _- ) greater than zero to the (+) - and (-) - Entries remain locked. 8. Device according to one of claims 5 to 7, characterized in that at the bridge diagonal points ( 16, 17 ) with a resistor ( 26 ) as an input resistor and a resistor ( 27 ) as a feedback resistor as a subtractor stage ( 24 ) connected differential amplifier ( 25 ) is connected. 9. Device according to one of claims 5 to 8, characterized in that the output voltage of the differential amplifier ( 25 ) for the case of constant current control is proportional to the voltage difference (U₁₁-U₁₃) to a constant (U₁₁) and that the proportionality factor is adjustable by the resistance ratio of the resistors (R₂₆, R₂₇).