DE1273844B - Inductive measuring device - Google Patents

Description

Inductive measuring device The invention relates to an inductive measuring device Measuring device, in particular for flow measurement, whose induced by an alternating field AC voltage in a transformer with an anti-phase constant frequency Compensation voltage is compared and the differential voltage after amplification is fed to a phase-controlled rectifier, the output of which for measurement serves, and that means for compensating the occurring in the induced circuit 900 phase-shifted interference signals are provided.

In measuring devices of this type that have become known, the Hall voltage a Hall generator as compensation voltage and the amplified rectified Control current of the Hall generator used as a measured variable. To compensate for the Stray fields caused interference signals must lead away from the electrodes be perfectly symmetrical. This perfect symmetry is when the measuring device is installed in a system practically not attainable, so that additional symmetry circuits become necessary in order to bring about an adjustment which enables the highest measuring accuracy.

The invention is based on the object of an accurate measurement without to obtain additional symmetry circuits and time-consuming adjustment measures.

The task at hand is achieved in a simple manner in accordance with of the invention in that the amplified differential voltage is one for the in phase with the alternating field component and one for the phase shifted by 900 Component is selectively fed to phase-controlled electronic rectifier, which rectifier each downstream, non-linearly controllable electronic Blocking oscillators for generating pulses with the amplitudes of the alternating voltage components control corresponding frequencies, and the pulses of the blocking oscillators respectively a downstream electronic one fed by the exciting alternating voltage Control amplitude replicas so that theirs to the transformer as compensation voltage supplied output quantities are linearly proportional to the alternating voltage or the Interference signals are, and that the output pulses of a blocking oscillator as integrable Serve measured variable.

The blocking oscillator arranged in the compensation circuit for the measurement signal a pulse train can be picked up, the frequency of which is linearly proportional to the is a pure measured variable.

Advantageously, mechanical servo systems can be omitted a load-independent direct current quantity can be derived from the pulses.

The invention allows a number of advantages.

This means that the output signals can easily be converted into Signals of any direct current limits for measuring and controlling. The DC part the system is adaptable to an external supply source and to remote loads with a minimum of interconnection lines to a remote utility connectable. The mode of operation of the device is also independent of changes in the Load resistances within wide limits. The linearity is better than + 0.250 / 0 of the maximum output. There are no changes in the conductor voltages of + 100 / o Display change by more than + ° / o of the maximum.

The device is also very independent of temperature fluctuations. Between -25 and Q550 C no error of more than + 0.25% of the maximum is generated. at Use of the apparatus with electromagnetic flow meters can make measurements Made with conductivities between electrodes of less than 20micromhos will. There is also a setting option for generating a full scale deflection at flow rates in the range 1:10.

Further details of the invention are based on the in the drawing illustrated embodiment explained in more detail.

A pipe 2 is traversed by a liquid whose Flow is to be measured.

An electromagnet creates a magnetic field perpendicular to the direction of flow. The field is indicated by an or caused several windings 4, which are connected to an alternating current source 6 with, for example, 60 Hz, wherein the winding 4 is in series with the primary winding 8 of a toroidal converter 10.

The electrodes 12 in contact with the medium are perpendicular to the direction of flow and perpendicular to the direction of the magnetic field. In a familiar way the flowing liquid generates an alternating current signal on the electrodes, the is substantially proportional to the flow rate. With the measuring electrodes 12, the two secondary windings 16 and 18 of a transformer 13 are connected The primary winding 14 of the transformer receives an input variable, which is the electrode signals should cancel, the connections being made so that a difference signal between the conductors 20 and 22 connected to the secondary windings occurs. The primary winding 14 thus generates a quadrature signal (signal out of phase by 900) for compensation of the quadrature components (components out of phase by 900) of the output quantity one of the following amplifiers.

A capacitor 23 acting as a high-pass filter bridges the primary winding 14 of the transformer; both are grounded through the capacitor 25.

The conductors 20 and 22 feed the primary winding of a matching transformer 24, which is bridged by a capacitor 26. The secondary winding of this matching transformer is bridged by a capacitor 28 for adaptation to the feed frequency. the Secondary winding of the matching transformer 24 feeds a highly sensitive Amplifier of a known type, which the transistors 32, 34 to 38 and 40, so that a high accuracy of the amplifier is guaranteed is.

The output of the amplifier leads via conductor 44 and the resistor 46 to a relatively phase-controlled electronic rectifier, namely for Primary winding 48 of an auxiliary transformer 42, the first secondary winding 50 has a center tap which is connected to a line 52, the other Connection shown in Fig. 2 and will be specified in more detail. The secondary winding 50 is matched to the supply frequency by a capacitor 54. The terminals of the secondary winding 50 are connected to the collectors of two cooperating transistors 56 and 58, the former being of the npn and the latter of the pnp type. The emitters of the said Transistors are connected in series with a diode 60 and a resistor 62 connected, between earth and a negative terminal of the supply network. the Bases of the transistors 56 and 58 are resistors 64 and 66 which are equal to one another connected to a common conductor 68, whose further connection with further Circuit parts in F i g. 2 is shown. The circuit described above demodulates the quadrature residual signals (residual signals out of phase by 90 °) of the amplifier.

A second secondary winding 70 of the auxiliary transformer 42 is with connected to a very simple demodulator circuit. The secondary winding 70 is through a capacitor 72 matched to the base frequency. Your terminals are with the collectors two transistors 74 and 76 connected, one from the pnp and the other is of the npn type.

Both are connected to their emitters between a diode 78 and a resistor 80 connected between the positive supply terminal and earth. Their bases are across equal resistors 82 and 84 to conductor 86 in Connected, according to F i g. 2 is connected to other circuit parts.

The center tap of the secondary winding 70 is via the conductor 88 with resistor 90 to the base of the transistor used as a DC amplifier 92 connected, the emitter of which is connected to the positive supply terminal via the resistor 94 is connected. Its collector is via a series connection of two resistors 96 and 98 grounded, the latter being bridged by a switch 100 can. The connection between resistors 96 and 98 is to the base of the as well transistor 102 used as a DC amplifier connected, the emitter of which grounded and its collector connected to the positive terminal via the capacitor 104 is. A DC connection between the collector of transistor 102 and the The base of a transistor 114 goes through the resistor 106 and a winding 108 of the Transformer 110 as well as the conductor 112 The transformer 110 forms together with the transistor 114 a blocking oscillator, which is used to generate variable pulses.

In normal operation, the blocking oscillator generates pulses with a frequency considerably higher than the alternating supply frequency. The emitter of the Transistor 114 is connected to the positive terminal of the supply source, whereas the collector via the winding 116 of the transformer 1l0 and via an RC circuit 118 and 120 is connected to the negative terminal. As in more detail below executed, the pulses generated by the blocking oscillator control a DC auxiliary voltage at the base of transistor 114 resulting from the demodulation of the amplifier's signals originates and which is passed via the secondary winding 70 of the auxiliary transformer 42 will. The winding 122 of the transformer 110 gives an output pulse which is about the conductors 124 and 126 according to FIG. 3 is passed on. The lower terminal of the winding 116 is connected to a plurality of circuit elements via conductor 128.

This connection goes to the negative terminal via the opposite directional diode 130. Conductor 128 is through resistor 132 to the base of transistor 134, which is grounded on the emitter side. His collector is connected to conductor 146 via resistor 142. The conductor 128 is still fed via the parallel RC circuit 136 and 138 to the base of the transistor 140, whose emitter is grounded ebeiifa% fls. It should be noted here that the transistors 134 and 140 are different types. The collector of the mains-fed amplitude mapper Serving transistor 140 is connected to conductor 146 via resistor 144. The collector of transistor 140 is also variable through conductor 148 Resistor 150 with a variable weakening circuit 152 and across the resistor 166 connected to conductor 168. Grounded resistors 160 and 162 are with theirs Connection point 158 through a capacitor 156 to the variable resistor 150 and connected to the weakening circuit 152 via the conductor 170. Of the The output of the weakening circuit is taken from the potentiometer 174, its sliding contact above a resistor 176 is connected to conductor 178 leading to primary winding 14 of the transformer 13 leads. The secondary winding of the ring transformer 10 feeds Network 180. Its capacitor 182 bridges the secondary winding of the toroidal converter 10, one terminal of which with the one shown in FIG. 2 continued conductor 196 is connected. The other secondary winding is connected through a variable resistor 184 to a conductor 192 connected, which is connected to the conductor 154 connected to the conductor 146 in connection stands. A variable resistor 186 is inserted between conductors 192 and 196. A grounded voltage divider with two equal resistors 188 and 190 is between the conductors 192 and 196 inserted, which still have another resistor 194 together connects. Furthermore, a potentiometer 198 is interposed, its adjusting contact connected to conductor 164.

One shown in FIG. 2 continued line 200 is to the upper terminal the primary winding 14 of the transformer 13 and the ungrounded surface of the capacitor 25 connected.

Referring to Fig. 2, conductors 146 and 196 lead to the bases of the transistors 202 and 204, which are connected via emitter resistors 206 and 208 to the positive terminal of the network are connected. The emitter of transistor 202 is across conductor 212 and the Resistor 214 to the collector of transistor 278, the emitter of the transistor 204 connected to line 200 via conductor 168 and resistor 210.

The top terminals of resistors 210 and 214 are through with each other the series circuit of resistor 216 is connected to a capacitor 218.

The emitter of transistor 202 is also through the capacitor 220 and resistor 222 connected to the base of transistor 224, which is still is connected to the negative pole via resistor 226. The emitter of the transistor 204 is connected to the base of transistor 224 through a resistor 228. The transistor 224 forms an amplifier. Its collector resistance 232 is over the capacitor 230 is connected to the conductor 68.

The emitter of transistor 204 is through capacitor 234 and the resistor 236 is connected to the base of the transistor 238 through the resistors 240 and 242 contains a bias voltage as a voltage divider. The voltage divider is placed between the positive and negative terminal for this purpose. The collector of the transistor 238 is connected to the negative terminal through a load resistor 243; he gives an output on conductor 86 via capacitor 244.

The base of a transistor 246 serving as a DC amplifier is connected to line 52 through resistor 248 and through the capacitor 250 connected to the negative terminal. The transistor 246 forms a DC amplifier, whose emitter is connected to the negative terminal via resistor 254 and its collector connected to the positive terminal via the capacitor 252nd is for generating a DC output through resistor 256, the Leite; 258 and the winding 260 of a transformer 261 which is the base of the transistor 262 leads, which together with the transformer forms a second blocking oscillator. The emitter of transistor 262 is connected to the positive supply terminal via the resistor 264 connected and its collector to the negative terminal via the secondary winding 266 and a resistor 268 out. A current-permeable in the manner shown Diode 270 is between the collector of transistor 262 and the negative terminal arranged. The output of the blocking oscillator is via the capacitor 272 and the RC element 274, 276 to the base of the network-guided amplitude mapper used transistor 278, whose collector with the connection between resistor 214 and capacitor 218 is connected, while its emitter is connected the positive terminal is applied.

In Fig. 3 is conductor 126 leading from winding 122 of the transformer 110 in FIG. 1 goes out, through resistor 280 and a diode 282 to the connection placed between the two resistors 284 and 286, which are in series with the zener diode 288 and the temperature-dependent diode 290 are connected to the two supply terminals is. In addition, conductor 124 leads from secondary winding 122 of the transformer 110 for connection between resistors 284 and 286.

A switching transistor 292 is connected to that acting as a signal converter Power transistor 294 connected in series, its collector with a heat sink 296 is connected. The emitters of both transistors are connected by conductor 298 and put together via the resistor 306 to minus.

The collector of transistor 292 is connected to the negative supply terminal connected via the resistor 300 and its base via the RC element 302, 304 led to the conductor 126.

The collector of transistor 294 is direct through capacitor 308 and by a motor 310, a resistor 312 for remotely controlling the load according to FIG the value of the set resistor 314 and this fed to the positive terminal. The load can be measured by remote control measuring devices known per se from the displaying or writing type. In the latter case, the external resistance value becomes greatly changed by resistor 314 without noticeable changes in the Current occur at the collector of transistor 294. The ends of resistor 312 are provided with terminals 316 to which a suitable millivoltmeter is connected can be. The motor 310 and the resistors 312 and 314 form a DC measuring circuit.

Afterwards the compensation takes place in a purely electrical way, whereby Pulses can be used, which varies both in frequency and in duration can be. The impulses, which are variable in frequency and duration, result in one Direct current with a precisely defined amplitude, which is an exact measure of the flow velocity is when the article according to the invention in connection with a flow meter is used. Otherwise, the DC output values result in a corresponding one Measure for the variables to be monitored in each case.

The electrode signals are applied to the windings of the transformer 13 fed. The primary winding 14 gives a compensation signal with one in phase and one component out of phase by 900. The unbalanced one The difference signal of the conductors 20 and 22 reaches the input of the amplifier and from there to the emitter of transistor 40. The amplifier stabilizes and keeps the deviations of the quadrature signal small in a manner known per se.

The output variable appearing at the emitter of transistor 40 becomes fed through resistor 46 to primary winding 48 of auxiliary transformer 42, its secondary windings 50 and 70 are parts of a selectively phased rectifier for the in-phase signal component and the 900 phase-shifted signal component. First of all, the in-phase component, that of the secondary winding, should be considered 70 is assigned. Synchronous demodulation is known and is therefore not necessary to be explained in more detail. The pnp and npn transistors 74 and 76 constitute switching means which are dependent on in-phase square waves of conductor 86. These Transistors are essentially fed from the output of secondary winding 70 of the auxiliary transformer 42. They work so that the in-phase component an amplifier output converted into a direct current signal with alternating components which latter are filtered out by the RC element 90, 91. The DC signal its polarity depends on the direction of the deviation and becomes the base of transistor 92 for direct current amplification. Quadrature signals and scatter signals other frequencies do not add anything to the DC signal at the base of the transistor 92 at.

DC amplification is also done by transistor 102, the bias voltage via resistor 106 and winding 108 of transformer 110 biased to the base of transistor 114 of the blocking oscillator, which in usual Way reacts with its winding 116 on the winding 108. The blocking oscillator is designed so that it can be used in the usual work areas for which it is intended is, gives impulses, the frequency of which is the frequency of the electrode signals substantially exceeds.

Assuming that the network 180 from the ring converter 10 has an input signal receives, its in series with the winding 4 of the flowmeter primary winding 8 carry an output signal to ground via conductors 154 and 146.

It is important that the phase relationship in the various connecting lines preserved.

Negative pulses through conductor 128 are suppressed by diode 130 and only uses positive impulses. These positive pulses become the bases of the transistors 134 and 140 of the npn and pnp types. Because of the connection of their collectors with the alternating reference signal through conductor 154, the transistors generate leakage pulses from the reference signal in the junction of conductor 148 to attenuator circuit 152, the capacitor 156 smooths so that attenuator 152 is in phase 60 Hz signal is fed through the attenuator circuit 152 and the conductor 178 an in-phase compensating component in the primary winding 14 of the Transformer 13 causes. The coordination of the weakening circle 152 serves to record different ranges of the flow velocity with full scale deflection to be able to.

A single department pulse can have any duration, albeit the circuit elements are dimensioned so that the pulse duration is always less than the space between the pulses of the Blocking oscillator in the highest vibration range is.

A single pulse for deriving the AC reference signal is the Output signal made proportional in its duration and the size of the reference signal the duration of the discharge. If one looks at a series of impulses, it follows that that the total component is proportional to the product of the frequency of the derivative signals and its duration is provided that the duration does not change very quickly changes. In other words, the conditions for each full wave of the derived Vibration proportional to the integral of the product of the frequency duration and are the amplitude of the derivative quantity. The derivative signal then picks up faster too than its frequency. The frequency, which is mainly due to the bias on the Base of transistor 114 is changed, changes greatly even with small changes of the difference signal, which via the matching transformer 24 to the amplifier is fed. The pulse duration changes z. B. with the frequency change. the Changes in pulse duration are generally during one cycle of the derivative quantity small. The compensation variable is opposite to the electrode signal, so that an elimination of the component lying in phase is achieved.

So far, the generation of an alternating current signal has been described is fed back and that has an amplitude that is exactly proportional to the electrode signals is. However, alternating currents cannot be measured precisely without considerable additional effort and great care to prevent mistakes.

The main object of the invention is therefore to convert the Dissipation into a direct current, which enables a very precise measurement of the flow rate. For this purpose, the transformer 110 has a third winding 122, whose output pulses Via the conductors 124 and 126 the circuit according to Fig. 3, the direct current converter, fed ~.

First consider a period of rest between the pulses, in which no pulses occur, although the working range is selected so that pulses a lower frequency can always be generated by the blocking oscillator. The as Signal converter serving power transistor 294 is of the npn type and its emitter connected to the negative supply terminal via resistor 306, while his The base is connected to the lower terminal of the zener diode 288, which is connected via the series circuit of resistors 284 and 286 is connected to the positive terminal. The upper The terminal of the Zener diode 288 is through the diode 290 intended for temperature compensation connected to the negative terminal. The base of power transistor 294 is permanently connected to a positive fixed potential (e.g. 9 V). In the current blocking state of transistor 292 it is important that the through the emitter of the power transistor 294 current flowing through resistor 306 is kept constant. It is known, that a current generated in this way is almost independent of that of the collector of the transistor supplied potential as long as it remains unchanged. The electricity to the collector flows from the positive terminal through resistors 314 and 312 and motor 310. The resistor 314 can be varied widely depending on the upcoming load. the A remotely controllable DC current meter can be used of the displaying or writing type or it can be a control element of the usual type be. An advantage of the invention is that it offers great freedom in the Size of the load allowed and also very independent of changes in the supply voltage is. In the resting state, the direct current flowing through the load should have a certain value Have a minimum value other than zero, with resistor 306 being on conditional, which allows a current of about 4 mA to flow in the rest period.

So it is the transistor 292 current blocking during the idle period. This is because its base normally has a positive potential applied to its emitter because of the connection via the resistor 302, conductor 126, winding 122 and conductor 124 for connection between resistors 284 and 286.

This connection is positive to the base of power transistor 294 and its emitter.

Positive pulses in the conductor 126 compared to the conductor 124 bring the Base of transistor 292 in an even more positive polarity and thus keep the current blocking State upright. In contrast, negative impulses (discharge impulses) cause the conductor 126 that the base of the transistor 292 goes negative, the diode 282 the current locks. If the pulses have a sufficient amplitude, the result is a more current-permeable one State of transistor 292. Resistor 300 is mainly used for setting the current from the emitter of the power transistor 294 (parallel to resistor 306), whereby pulses are generated that have a relatively large but fixed amplitude to have. This makes the current independent of the collector potential.

A large capacitor 308 smooths the one Direct current through resistors 314 and 312 and motor 310 (direct current measuring circuit) can flow which is very precisely proportional to the integrated product of the frequency time pulse duration is. Since the compensating alternating current is proportional to the electrode signal, is it is also proportional to the integral of the derivative quantity.

The generated direct currents enable an accurate measurement of the electrode signal.

The quadrature signals must be suppressed if possible, otherwise they cause trace signals that are in phase due to a phase deviation can whose suppression is controlled by a discriminator that works with the Secondary winding 50 of the auxiliary transformer 42 is connected. According to FIG. 1 contains the selective phased rectifier transistors 56 and 58.

Their connections are only for the in-phase ones for simplicity Signals described. The conductor 68 carries switching square waves to the base thereof Transistors. Their output variables are transmitted via line 52 to the direct current amplifying Transistor 246 led, which controls the base voltage of transistor 262, which in turn is connected to the feedback transformer 261.

The reference signal is derived from conductor 146 through the emitter of the Transistor 202; it is in phase.

The derivative quantities are carried via line 200, which according to FIG Fig. 1 is connected to the ungrounded surface of the capacitor 25, which a phase shift of the resulting AC component of the quadrature signal contrary to the quadrature component of the transformer 13 results. That way will automatically achieved a compensation of the quadrature signal. It consists in this Case no interest in measuring the quadrature signals, just eliminating them.

Finally I want to work on the part of the circuit that is covered by the conductors 146 and 196 according to FIG. 2 extends to conductors 68 and 86, reference should be made. The emitters of transistors 202 and 204 affect transistors 224 and 238 for generating square waves in the conductors 68 and 86, the aforementioned Discriminators are supplied, with phase shifting means in the form of RC elements are provided.

Claims (6)

Claims: 1. Inductive measuring device, in particular for flow measurement, their alternating voltage induced by an alternating field in a transformer an anti-phase equal frequency compensation voltage is compared and the Differential voltage fed to a phase-controlled rectifier after amplification is, the output of which is used for measuring, and that means for compensating the 900 phase-shifted interference signals occurring in the induced circuit are provided are, d a d u r c h g e - indicates that the amplified differential voltage is a for the component that is in phase with the alternating field and one for the component around 900 phase shifted component selectively phased electronic rectifier (42, 70, 74, 76 or 50, 56, 58) is supplied, which rectifier is each downstream, non-linearly controllable electronic blocking oscillators (110, 114 or 261, 262) to generate pulses with the amplitudes of the AC voltage components corresponding Control frequencies, and the impulses of the blocking oscillators each have a downstream, Electronic amplitude replicas fed by the exciting alternating voltage (140 resp. 278) so that their the transformer (13) as a compensation voltage supplied output quantities are linearly proportional to the alternating voltage or the Are interference signal, and that the output pulses of a blocking oscillator (110, 114) serve as a measurable variable that can be integrated. 2. Measuring device according to claim 1, characterized in that the Compensation voltage of the primary winding (14) of the transformer (13) is supplied whose two secondary windings (16, 18) on the one hand with the measuring electrodes (12) and on the other hand via a matching transformer (24) with a highly sensitive, stabilizing electronic amplifier (32 to 40) are connected to its output is connected to the primary winding (48) of an auxiliary transformer (42) whose both secondary windings (50, 70) parts of the two phase-controlled rectifiers form. 3. Measuring device according to claim 1 or 2, characterized in that that each of the two phase-controlled rectifiers has at least one single-stage electronic DC amplifier (92, 102 or 246) is connected downstream. 4. Measuring device according to claim 1, 2 or 3, characterized in that that the network-commutated amplitude mapper (140) for the in-phase component the compensation voltage on the output side via a variable the measuring range Weakening circuit (152) connected to the primary winding (14) of the transformer (13) is. 5. Measuring device according to one or more of the preceding claims, characterized in that the one generating the output pulses that can be used as a measured variable feedback blocking oscillator (110, 114) a transformer (110) with a third Has winding (122) from which the measuring pulses can be removed. 6. Measuring device according to claim 5, characterized in that the third winding (122) of the transformer (110) an electronic signal converter (294) controls the current flowing through a direct current circuit (310, 312, 314) which is exactly proportional to the integrated product of the pulse frequency and the pulse duration is. Publications considered: German Auslegeschriften No. 1,010,634,1028,222; Graue: Electrical measurement of non-electrical quantities (1962), Pp. 48 to 50, Akad. Verlagsges. Leipzig.