GAS FLOW MEASURING CIRCUIT AND GAS FLOW SENSOR

Abstract

A gas flow measuring circuit includes at least one reference resistor and at least one variable resistor that varies in accordance with the characteristics of the flow of a gas and means for determination of the difference between the reference resistor and variable resistor, with at least one current loop arrangement including first current source means coupled in series with said reference resistor and second current source means coupled in series with said variable resistor wherein both resistors are connected to ground for providing an ideally constant current through the respective resistor to produce first voltages across the reference resistor and second voltages across the variable resistor, and voltage measuring means for measuring the voltage difference between said reference resistor and said variable resistor to produce a characteristic voltage difference representative of the characteristics of the gas.

Claims

1. A gas flow measuring circuit comprising at least one reference resistor outside the gas flow and at least one variable resistor that varies in accordance with the characteristics of the flow of a gas and means for determination of the difference between said reference resistor and variable resistor, wherein the at least one reference resistor is arranged outside the gas flow and is at least by a factor of 10 less temperature sensitive than the at least one variable resistor, at least one current loop arrangement comprising first current source means coupled in series with said reference resistor and second current source means coupled in series with said variable resistor wherein both resistors are connected to ground for providing an ideally constant and equal current through the respective resistor to produce first voltages across the reference resistor and second voltages across the variable resistor, and voltage measuring means for measuring the voltage difference between said reference resistor and said variable resistor to produce a characteristic voltage difference representative of the characteristics of the gas.

2. The gas flow measuring circuit according to claim 1, wherein current source multiplexing means alternately electrically coupling the first current source means and the second current source means in series with the reference resistor and the variable resistor, respectively.

3. The gas flow measuring circuit according to claim 1, wherein at least of two separate resistors in series as reference resistor and reference resistor input multiplexing means alternately electrically switching one input of the voltage measuring means to at least one of the separate resistors in series representing the reference resistor with the variable resistor connected to the other input of the voltage measuring means.

4. The gas flow measuring circuit according to claim 1, wherein at least one further variable resistor and variable resistor multiplexing means alternately electrically coupling the variable resistors in series with the respective current source means so that one of each current source means is connected to one of the variable resistors and the other one of each current source means is connected to the reference resistors and each variable resistor is compared with the reference resistor.

5. A gas flow sensor comprising sensor arrangement with a heating element and a controller, and a gas flow measuring circuit according to claim 1, including a set of variable resistors as a set of sensing elements in the gas flow, wherein at least one of the resistors works as at least one of a gas temperature sensor, an upstream sensor, and a downstream sensor.

6. The gas flow sensor according to claim 5, wherein the controller is adapted to control at least of two separate resistors in series as reference resistor by alternately multiplexing the one input of the voltage measuring means to at least one of the separate resistors in series representing the reference resistor.

7. The gas flow sensor according to claim 5, wherein the controller is adapted to control from the set of sensing elements a subset of sensing elements according to a defined measurement method.

8. The gas flow sensor according to claim 7, wherein for calorimetric measurement of the gas flow the controller is adapted to use from the set of sensing elements the heating element, the gas temperature sensor, at least one upstream resistor and/or at least one downstream sensor, and at least one reference resistor.

9. The gas flow sensor according to claim 8, wherein the controller is adapted to control the heating element to a defined temperature at a setpoint, to control the at least one upstream resistor and at least one downstream resistor by multiplexing these resistors and coupling them alternately in series with the respective current source means so that each upstream resistor and downstream resistor is supplied with an ideally constant and equal current and is compared with the reference resistor, to determine relevant data concerning the gas flow received from the voltage measuring means depending on the received voltage difference between said reference resistor or reference resistors and said at least one upstream and at least one downstream resistor.

10. The gas flow sensor according to claim 7, wherein for anemometric measurement of the gas flow the controller is adapted to use from that set of sensing elements the heating element, the gas temperature sensor, and, in case that a gas temperature measurement additionally is performed, the reference resistor.

11. The gas flow sensor according to claim 10, wherein the controller is adapted to control the heating power for the heating element on a constant temperature setpoint depending on the temperature of the gas temperature resistor and to determine relevant data concerning the required heating power and its changes.

12. The gas flow sensor according to claim 7, wherein for time of flight measurement of the gas flow the controller is adapted to use from that set of sensing elements the heating element, at least one upstream and/or at least one downstream sensor, and optionally to use the gas temperature sensor for defining an average setpoint and optionally to use the reference resistor in case of a comparison of the gas temperature sensor to one or more reference resistors.

13. The gas flow sensor according to claim 5, wherein the controller controls the measurement of the gas flow depending on the requirements by two of the measurement principles calorimetric measurement, anemometric measurement, and time of flight measurement and determines the gas characteristics.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0056] The figures show:

[0057] FIG. 1 a gas flow measuring circuit using two identical current sources;

[0058] FIG. 2 a gas flow measuring circuit adding the capability of selecting which current source is connected to each resistive element;

[0059] FIG. 3 a gas flow measuring circuit allowing to measure one additional variable resistor;

[0060] FIG. 4 a gas flow measuring circuit suitable for accepting a wide range of variable resistors values;

[0061] FIG. 5 a block diagram of the gas flow sensor with multiplexing means for the current sources and several variable resistors;

[0062] FIG. 6 a block diagram of the gas flow sensor with a gas flow measuring circuit suitable for accepting a wide range of variable resistors values; and

[0063] FIG. 7 a schematic overview of the sensing elements.

DETAILED DESCRIPTION

[0064] FIGS. 2 to 4 show some schematic exemplary variations based on a schematically depicted basic gas flow measuring circuit 11 with a current loop arrangement shown in FIG. 1. As shown in the depiction above, the chip used as a gas sensor is arranged in the usual manner and know from the prior art on a carrier and comprises a membrane made from an insulating material. A gas temperature sensor is arranged on the chip and the heater as well as (for example in the depiction) two upstream sensors (US Sensor 1 and US Sensor 2) and two downstream sensors (DS Sensor 1 and DS Sensor 2) with regard to the direction of the flow according to the arrow.

[0065] The schematic basic current loop arrangement of the gas flow measuring circuit 11 shown in FIG. 1 comprises two independent current sources 1, 2, each being connect to ground 3 via a resistor 4, 5. Resistor 4 is in this embodiment reference resistor Rref and resistor 5 a variable resistor Rx. An instrumental amplifier 6 (subtractor) determines the voltage difference of the voltages at the resistors 4, 5. Therefore the inputs of the instrumental amplifier 6 (subtractor) are connected to the other side of the resistors 4, 5. In an idealized situation both current sources 1, 2 emit exactly the same current. In a real circuit two independent current sources 1, 2 will drift and emit slightly different currents, such current deviations would directly influence the measured signal.

[0066] According to FIG. 2 the current sources 1, 2 are switched by multiplexers 7-1 and 7-2 so that each current source 1, 2 can be alternately connected to each resistor 4, 5. As a consequence, the current sourced by each current source 1, 2 can be continuously monitored and the variable resistance of the resistor Rx can be precisely measured under the assumption that the current sources 1, 2 stay constant within two measurements.

[0067] As mentioned above the single elements or the current loop arrangement according to FIG. 1 in total can be expanded to sequentially measure several variable resistors Rx or may be modified to measure several variable resistors Rx in parallel by using more current sources 1, 2, more multiplexers 7-1 and 7-2 and more reference resistors Rref (each parallel measurement requires two additional current sources 1, 2, one additional reference resistor Rref, suitable multiplexers 7-1 and 7-2 and one more subtractor 6). The measurement of additional variable resistors Rx requires a multiplexer 7-1 and 7-2 supporting more connections so that each variable resistor 5 is compared with the reference resistor Rref.

[0068] In the gas flow measuring circuit 11 according to the embodiment of FIG. 3, the multiplexers 7-1 and 7-2 of FIG. 2 are extended in order to measure two variable resistors Rx1 and Rx2. As shown, the multiplexers 9-1 and 9-2 of current loop arrangement allow to switch the reference resistor Rref 4 and the variable resistor Rx between the current sources 1, 2 and between the resistors 5, 5 being variable resistors Rx1 and Rx2, respectively. The following table shows the different switching positions:

TABLE-US-00002 Multiplexer Multiplexer Current Current 9-1 9-2 Source 1 Source 2 a b Rref Rx1 a c Rref Rx2 b a Rx2 Rref c a Rx1 Rref

[0069] According to FIG. 4 three reference resistors 4a, 4b, 4c are connected in series. A multiplexer 18 can be set to position a so that the three resistors 4a, 4b, and 4c are connected, thus realizing Rref=R4a+R4b+R4c. By setting position b, the two resistors 4b and 4c are connected in series, thus realizing Rref=R4b+R4c. Finally, by setting position c, only the resistor 4c is connected in series, thus realizing Rref=R4c. In difference to FIG. 3 the resistors are not switched between the current sources 1, 2. Selecting the multiplexer position thus allows to select a value for the reference resistor and to deliver the most appropriate reference voltage suitable for measuring the variable resistor by mean of the instrumental amplifier (subtractor) 6. The number of reference resistors connected in series may be varied according to the desired range.

[0070] FIG. 5 shows a schematic block diagram of an embodiment of a gas sensor 12 according to the invention comprising a gas flow measuring circuit 11 with the gas sensor current loop arrangement similar to the embodiment of FIG. 3 with its output from the subtractor 6 being connected to an analog/digital converter 13 which output is connected to a controller 14. The controller 14 controls via a heater control 15 a heater 17 in form of a resistor. The controller 14 further controls a multiplexer 16-1 and a multiplexer 16-2 similar to the embodiment of FIG. 5 of the gas flow measuring circuit 11 as well as the current sources 1, 2. The gas flow measuring circuit 11 comprises in this embodiment a resistor 4 as reference resistor Rref and variable resistors 5, 5 and 5 acting as gas temperature resistor Rt, upstream resistor Rus1 and downstream resistor Rds1, respectively. The connection of these resistors Rref, Rt, Rus1, and Rds1 with the multiplexer 16-1, 16-2, respectively, leads to the following switching positions for a sensor measurement:

TABLE-US-00003 Multiplexer Multiplexer Current Current 16-1 16-2 Source 1 Source 2 a b Rref Rt a c Rref Rus1 a d Rref Rds1 d a Rds1 Rref c a Rus1 Rref b a Rt Rref

[0071] FIG. 6 shows the schematic block diagram similar to the block diagram of FIG. 5 with an embodiment of a gas sensor 12 according to the invention comprising a gas flow measuring circuit 11 with the gas sensor current loop arrangement similar to the embodiment of FIG. 4. There is no switching of resistors Rref and Rx between the current sources 1, 2, but a selection between the reference resistors 4a, 4b, 4c by the multiplexer 18 and a selection between the variable resistors 5, 5, 5 by the multiplexer 16.