DE1241133B - Circuit arrangement for gas flow measuring transducer to correct the display after more than two state quantities of the gas - Google Patents

Description

Circuit arrangement for gas flow transducers for correcting the Display after more than two state variables of the gas To correct the measured value of flow transducers with electrodynamically acting force compensation of the Measuring mechanism deflections are known computing circuits that consist of a resistor network, usually a bridge circuit, which is connected upstream of the transmitter. The electrical quantity taken from the network is used for correction using one of the existing ones or an additional winding of the compensation system.

The resistances of the network are dependent on two state variables, according to which corrections should be made, e.g. B. pressure and temperature adjusted. The measuring devices for the state variables there is either a direct electrical output variable Resistance (e.g. resistance thermometer), or the output variable is set to mechanical Ways, e.g. B. via a potentiometer, converted into a resistor. Be multiple but for the measurement of the state variables transmitter in compensation circuit used, in the output of which the measured value appears in the form of an impressed current. Complex auxiliary equipment is then necessary to manage the impressed current for processing in the computing circuit into a corresponding resistance value to reshape.

It is also known in a flow transducer to have two correction variables, Pressure and temperature to be taken into account that the correction values proportional Voltage drops can be compared via a compensation amplifier. The compensation amplifier controls the current that flows through the one correction resistor in such a way that that a voltage drop occurs which is equal to the voltage drop that occurs across the other correction resistor is present. With this circuit, too, it is necessary to that the parameters pressure and temperature, according to which the measured value is to be corrected, can be converted into proportional resistance values.

The invention is based on the object of a correction circuit to be specified for more than two correction values for which both transducers are used which can be converted into a resistance value, which is the quantity to be corrected for transform, as well as those that deliver this quantity as an impressed current, the one Hall multiplier feeds. According to the invention this is achieved in that a the number of amplifiers connected downstream, adapted to the number of state variables is present in compensation circuit and each of these amplifiers is known per se Two voltage drops across the Hall multipliers introducing the correction variables or resistances thereby equalizing each other that by means of its output current one of the two to be compared - voltage drops can be changed, and that the Output current of the last amplifier via one of the existing or the additional Winding of the compensation system of the transmitter is performed.

The circuit is set up in such a way that the flow equation is as close as possible to the state variables in accordance with the relationship is corrected.

Q = flow rate, A = device constant, d P = differential pressure, f (K) = the correction function to be derived according to the effective state variables.

Some embodiments for such computing circuits are intended will be explained in more detail with reference to the drawing.

The F i g. 1 and 2 relate to correction circuits for only two state variables pressure and temperature, while in the circuit according to Fig. 3 the weight is also included as a third state variable. The specified Circuits can of course be based on other state variables, for example the Extend the humidity or the calorific value of a gas flow recorded by the flow transducer. For this purpose, the correction function is to be derived and further circuit elements are accordingly with reverb multipliers.

In the circuit according to FIG. 1 is a depending on the State variable "temperature" of the medium adjusted ohmic resistance RT in the output circuit of the flow transmitter. That of another state variable, in the example described the figure to the pressure P of the medium, proportional impressed current ip flows through it a reverb multiplier horn, and is there with a stream of the arithmetic circuit multiplied as the output current of the amplifier V the winding W1 of the electrodynamic Compensation system feeds. The amplifier V compares that proportional to the product Voltage value of the Hall multiplier at electrodes 1 and 2 with the voltage drop at the resistance RT, which is set according to the temperature of the measuring medium.

According to the schematic representation of FIG. 1 becomes the balance beam 3 of the flow transducer at the left end deflected by a force that corresponds to the Differential pressure at a throttle point of the medium to be measured is proportional and which is effective on the diaphragm 4 shown schematically.

The deflection of the balance beam 3, which is rotatable about the point; will scanned in a known manner with an inductive tap - the one downstream Amplifier 7 modulates. The output current of the amplifier feeds in the example Drawing the field coil W2 and the plunger coil Wl deselectro via the series circuit dynamic compensation system 8. The output current i of the amplifier 7 represents itself in such a way that it interacts with the current J of the arithmetic circuit the right end of the balance beam3 an electromagnetic force is exerted, which compensates for the force acting on the diaphragm 4 and proportional to the differential pressure. - For this state of equilibrium, iIP is proportional to P -proportional to the product of currents i and J: iJ.

The amplifier V compares the voltage drop across the resistor RT, - - which is proportional to the temperature of the measuring medium, with the product voltage at electrodes 1 and 2 of the Hall multiplier and represents the current J, which the Field coil of the Hall multiplier flows through, so that the product voltage of the Voltage across resistor RT is the same and opposite to this. There the Hall multiplier impressed by a pressure proportional to the medium to be measured Current is flowing through, the relationship J.P i.T.

From the two given relationships one derives T #P ~ i².

P and from here If this relationship is compared with the relationship for Q given in the introduction, it can be seen that the output current i of the amplifier is proportional to the flow rate Q corrected for the values of temperature and pressure. The flow 1 can thus be displayed by means of a flow measuring instrument calibrated in flow units.

F i g. 2 shows a modified circuit, although it is also a has a resistance RT set according to the temperature of the measuring medium, in which, however, an additional coil 9 on the electrodynamic compensation system for correction is appropriate. The output current i of the amplifier 7 flows through it one after the other, the plunger coil W1 and the field coil W2 of the electrodynamic compensation system 8. The current i then flows through the resistor RT, the size of which corresponds to Temperature of the medium to be measured is set, and the coil 11 of the Hall multiplier Hml. The coil 11 is also connected to the output of the amplifier 28, so that the sum of the amplifier output current J and the current i of the flow transducer the magnetic field of the Hall multiplier builds up. The amplifier 28 compares the voltage drop across the resistor RT with the product voltage of the Hall multiplier and sends such a current J through the auxiliary winding 9 and the coil 11 that the product voltage of the voltage at the resistor RT is the same, but opposite is directed. The relationship applies to the compensation of the forces on the balance beam 3 zIP ~ i (i + J), i.e. H. the force on the left end of the balance beam, which the Differential pressure membrane 4 exerts, is counterbalanced by an electromagnetic counterforce, which is the product of the current i in the plunger coil and the sum of the currents i + J is proportional in the two field coils. The ones at terminals 1 and 2 of the hall multiplier resulting voltage is the product of the current J + i through the coil 11 and the Pressure of the medium to be measured is proportional, because an impressed one that is proportional to the pressure Stromip flows through the hall multiplier Hml. Thus, for the tensions in Amplifier input i (J + i) -P.

Eliminating 'J from these equations results in T AP ~ i2 P or The current in the output of the flow transducer i is thus again a measure of the corrected measured flow value and can be displayed or registered in a measuring instrument not shown in the drawing.

According to the embodiment of FIG. 3 become the state variables Temperature, density and pressure as impressed currents in three Hall multipliers Hml, H ,,, Hrna introduced. To simplify the illustration, only the Terminals for the output current 1 of the flow transducer 12 and 13 are shown and the terminals 14 and 15, which are connected to the auxiliary winding 9 of the electrodynamic Compensation system are to be connected and the correction current J is fed to it.

The impressed current iT, which is proportional to the temperature, is in the first Hall multiplier Hml multiplied by current 1 of the flow transducer, which flows through the field coil 16 of the Hall multiplier Hnzl. The compensation amplifier 17 compares the voltage value proportional to the product at electrodes 1 and 2 of the Hall generator with the product voltage of the second Hall multiplier Hrn at terminals 21, 22. The output current il of the amplifier 17 flows through the field coil 19 of the multiplier Hm2 and the field coil 23 of the multiplier Ohm3, which is from an impressed current bp proportional to the pressure of the measuring medium flows through it will. The current il is adjusted by the amplifier 17 so that the product voltage at the Hall multiplier H1n2 the product voltage of the multiplier H, n, equal and is directed opposite to this. Another compensation amplifier 18 compares the product voltage at the Hall multiplier H "with the voltage at one Ohmic resistance R. This comparison resistance R is once from the output current of the flow transducer i and also in the same direction from the output current J of the amplifier 18 flowed through. The amplifier 18 provides its output current J such that the voltage drop across the reference resistor R is the product voltage of the multiplier Hm3 is equal.

The flow transmitter with the electrodynamic compensation system is connected as in the earlier exemplary embodiments. The output current i flows through the plunger coil and a field coil, while the current J the additional field coil 9 dines. For the forces on the balance beam 3, the relationship nP - i (i + J).

At the input of the amplifier 17 are the oppositely connected Voltages at the electrodes 1 and 2 or 21 and 22 of the multipliers Hml and Hm2 are equal to each other, so that the relationship holds 1.T r y.

For the input of the amplifier 18 applies accordingly il P ~ (J + i).

If one eliminates the quantity il from the last two equations, then 1.T (J + 1) results. y If you insert this value into the first equation, you get γP 12 PT and from this Thus, the flow 1 of the flow transducer is again a measure for the corrected flow, independent of the existing pressure, the temperature and the density of the flowing medium.

In a similar way, as already mentioned, further correction variables, For example, take into account the humidity and the calorific value of a gas to be measured.

Claims (4)

Claims: 1. Circuit arrangement for gas flow measuring transducers with electrodynamic force compensation of the measuring mechanism deflection to correct the Display via one of the existing or an additional winding of the compensation system of the transmitter after more than two state variables of the gas, e.g. B. by temperature, Weight, pressure, humidity, these quantities either in a resistance value or an impressed current, but at least one of these quantities in an impressed Current is converted, which feeds a Hall multiplier, d u r c h e k e n nz ei c h n e t that a number adapted to the number of state variables is mutually exclusive downstream amplifier (17, 18 or 28) in compensation circuit available and each of these amplifiers has two voltage drops in a manner known per se on the Hall multipliers (H7n1, Hm2, Hm3) or Resistors (RT) are thereby adjusted to each other that by means of its output current one of the two voltage drops to be compared can be changed and that the Output current (J) of the last amplifier via one of the existing ones (W1) or the additional winding (9) of the compensation system of the transmitter is performed. 2. Circuit arrangement according to Claiml for correcting the display two state variables of the gas, e.g. B. Temperature and pressure, one size is converted into a resistance value and the other is converted into an impressed current, which feeds a Hall multiplier, characterized in that the amplifier (28) the voltage drop across the resistor (RT) to the voltage of the Hall multiplier (Hrn ,, terminals 1, 2) in that the field winding (11) of the Hall multiplier (Hrn,) the output current flowing through the voltage at the Hall multiplier (Terminals 1, 2) can be changed and the output current (J) via one of the existing (W1) or the additional winding (9) of the transmitter compensation system is. 3. Circuit arrangement according to Claim 2 with the modification that both State variables are converted into an impressed current and both currents are one each Feed reverb multiplier. 4. Circuit arrangement according to claim, characterized in that Applied currents proportional to the state variables temperature, weight and pressure Corresponding Hall multipliers feed that which is proportional to the temperature impressed current (tal) in the first Hall multiplier (Hrn,) with which the magnetic coil (16) of the Hall multiplier (H,) flowing output current (i) of the flow transducer is multiplied and a first amplifier (17) in compensation circuit the dem Product proportional voltage value of the first Hall multiplier (H, n1) with the Product voltage of the second, of which the weight proportional current flowed Hall multiplier (H "Z2) compares and that the output current (1,) of the amplifier (17) as the second multiplier the second Hall multiplier (Hrn,) and the third (Hm) was traversed by an impressed current (ip) corresponding to the pressure Hall multiplier (H », 3) feeds, while the second feeds the additional winding (9) Amplifier (18) the product voltage of the third Hall generator (Hm3) with the voltage at a resistor (R) comparing the amplifier output current (J) and the Flow through the output current (i) of the transmitter. Considered publications: German Patent Specifications No. 547 385, 742 822; German Auslegeschriften Nos. 1 020 413, 1 027 418, 1037714; German Patent application M 16868 IXb / 42a (published April 7, 1955); "Electronics", 1956, no. 2, pp. 47 to 49; "Siemens-Zeitschrift", 1954, Issue 8, pp. 370 to 376; sRadio-Mentor «, 1954, No. 11, p. 589.