EP1397647A2 - Excitation circuits for coriolis mass flowmeters - Google Patents

Abstract

The invention relates to an excitation circuit for a coriolis mass flowmeter (10), which is connected to a dual-conductor process control loop, is exclusively supplied with energy by the loop and emits a measuring signal exclusively via said loop. Said flowmeter comprises a vibrating measuring tube (1, 2) and an excitation assembly (6) for causing the tube to vibrate at an oscillation frequency, which is equal to the current mechanical resonant frequency of the measuring tube or is adjacent to said frequency. The flowmeter also has sensor assemblies (7, 8) which generate corresponding sensor signals, said assemblies being arranged along the measuring tube at a distance from one another. The excitation circuit comprises a peak value detector (pd), which is supplied with one of the sensor signals as an input signal, a comparison stage (sa), which determines a deviation of an output signal of the peak value detector from an adjustable reference signal (Sr) that predefines an amplitude of the vibration of the measuring tube, a multiplier (m) for the input signal of the peak value detector (pd) and an output signal of the comparison stage (sa), in addition to a final stage (ps) that supplies the excitation assembly, one input of said final stage being connected to the output of the multiplier. A pulse-duration modulator (pm) or a direct current converter (dc) and a comparator (kk) can be used in place of the multiplier.

Description

 Excitation circuits for Coriolis mass flow meters

The invention relates to excitation circuits for Coriolis mass flow meters connected to a two-wire process control loop, which are supplied with energy alone and which transmit a measurement signal solely via them. Such a mass flow meter is referred to below as a two-wire mass flow meter.

Coriolis mass flow meters have long been theoretically described and have also been known in their current form for around 25 years. This form, which is still common today, contains a mechanical transducer, which comprises at least one straight or at least one measuring tube bent in one plane or spatially and associated electronics, which is fixed on the inlet and outlet sides and which vibrates between these fixings during operation is excited.

The usual mass flow meters are mains-powered measuring devices and must have at least two electrical leads, i.e. conductors. The measuring signal representing the mass flow, in particular the proportional signal, is measured in accordance with a standard that is usual for this purpose, e.g. generated and output according to the current standard between 4 mA and 20 mA, a common frequency standard or a digital standard; this requires two additional conductors.

In EP-A 10 94 307, the possibility of equipping Coriolis mass flow meters with only two conductors, that is to say forming them as so-called two-conductor mass flow meters, is mentioned in passing and only briefly; There are no such two-wire mass flow meters on the market yet.

As can also be gathered from the cited EP-A, two-wire measuring devices generate an output current as the measurement signal, the instantaneous values of which represent a converter signal generated by means of a physical-electrical converter as proportionally as possible. The two conductors are used both for energy supply, for which purpose a direct voltage source is to be applied to the two conductors from the outside, and for the transmission of the measurement signal. In the case of two-wire measuring devices in accordance with the current standard between 4 mA and 20 mA mentioned, a specific current value within this current range corresponds exactly to a measurement signal value. Only the current range below 4 mA can be used to power the electronics of the two-wire measuring device. This means that the power supply is only available with a power in the order of 50 mW, which is referred to below as low power.

Due to these facts, two-wire measuring devices with the current standard between 4 mA and 20 mA are particularly well suited for use in potentially explosive environments.

Furthermore, two-wire measuring devices are often designed so that they can work with one of the usual fieldbuses. On the one hand, this can be done by connecting directly to the fieldbus, e.g. according to the FIELDBUS protocol (FIELDBUS is a registered trademark of the FIELDBUS FOUNDATION). On the other hand, the cooperation with the interposition of a bus coupler, e.g. according to the so-called HART protocol, indirectly (HART is a registered trademark of the HART User Group).

The electronics of Coriolis mass flow meters mentioned comprise an excitation circuit and an evaluation circuit. The excitation circuit is used to vibrate the at least one measuring tube through which the fluid to be measured flows.

The vibration takes place at an oscillation frequency which is equal to or adjacent to the instantaneous mechanical resonance frequency of the measuring tube; this is determined by the density of the fluid; the density in turn is known to depend on the temperature of the fluid. Therefore, conventional mass flow meters also contain at least one temperature sensor.

Since the mass flow - that is known to be the mass of fluid flowing per unit of time - is measured by means of the vibrating measuring tube, the evaluation circuit generates a corresponding measurement signal. The aforementioned small power available must be sufficient to supply the exciter and the evaluation circuit with energy. The evaluation circuit of EP-A 1059515, which corresponds to US patent application 09 / 579,384 dated May 20, 2000, is particularly suitable for this purpose. However, an excitation circuit that manages with so little supply energy has not yet been described by the prior art.

It is therefore an object of the invention to provide suitable excitation circuits for Coriolis mass flow meters with low power consumption and therefore especially for two-wire Coriolis mass flow meters.

To achieve the object, the invention consists in an excitation circuit for a Coriolis mass flow meter connected to a two-wire process control loop, which is supplied with energy alone and which outputs a measurement signal

at least one measuring tube vibrating during operation,

an electromechanical excitation arrangement for vibrating the at least one measuring tube at an oscillation frequency which is equal to or adjacent to an instantaneous mechanical resonance frequency,

a sensor arrangement reacting to vibrations of the at least one measuring tube for generating a first sensor signal representing inlet-side vibrations of the measuring tube and a second sensor signal representing outlet-side vibrations of the measuring tube, which comprises excitation circuit:

an amplitude demodulation stage for generating an output signal which currently represents an oscillation amplitude of the vibrating measuring tube, the amplitude demodulation stage being supplied with one of the sensor signals supplied by the sensor arrangement or the sum thereof as an input signal,

a comparison stage for determining a deviation of the detected oscillation amplitude of the vibrating measuring tube from a predetermined desired oscillation amplitude, the comparison stage being supplied on the input side with the output signal of the amplitude demodulation stage, which represents the desired oscillation amplitude, In a first variant, the excitation circuit according to the invention also comprises an amplitude modulation stage coupled on the input side to an output of the comparison stage for generating a driver signal for the excitation arrangement, which has a signal amplitude that is dependent on the determined deviation, the amplitude modulation stage on the input side including the deviation of the detected vibration amplitude from the predetermined one Error signal representing the desired vibration amplitude is fed to the input signal of the amplitude demodulation stage.

In a second variant, in turn, the excitation circuit according to the invention comprises a pulse width modulation stage coupled on the input side to an output of the comparison stage for generating a clocked driver signal for the excitation arrangement, which has a pulse width dependent on the determined deviation, the pulse width modulation stage on the input side including the deviation of the detected vibration amplitude from the error signal representing the predetermined target oscillation amplitude, the input signal is fed to the amplitude demodulation stage.

According to a preferred first embodiment of the invention, the amplitude demodulation stage comprises a peak value detector for detecting a signal amplitude of the input signal of the amplitude demodulation stage.

According to a preferred second embodiment of the invention, the amplitude demodulation stage comprises a preamplifier for the input signal of the amplitude demodulation stage.

According to a preferred third embodiment of the invention, a proportional, integrating and / or differentiating amplifier is provided in the comparison stage for generating the error signal.

According to a preferred fourth embodiment of the invention, the

Amplitude modulation stage an output stage with an operational amplifier, which is connected as follows:

- An inverting input is connected to a first resistor

Connected to ground, a non-inverting input is connected to a second resistor, which has the same resistance value as the first resistor, at the output of the multiplier,

- An output is connected with the interposition of a third resistor to a first pole of a primary winding of a transformer, a second pole of which is at the circuit zero, which transformer

- Has a secondary winding connected to the electromechanical excitation arrangement and

- is a step-up transformer,

- The inverting input is connected to the output via a fourth resistor, and

- The non-inverting input is connected to the first pole of the primary winding via a fifth resistor, which has the same resistance value as the fourth resistor.

According to a preferred fifth embodiment of the invention, the amplitude modulation stage comprises a complementary push-pull output stage, which is fed with a DC supply voltage that is dependent on the determined deviation.

Furthermore, the invention consists in a Coriolis mass flow meter with one of the aforementioned excitation circuits, the two-wire process control loop carrying a direct current which serves to supply energy.

According to a preferred embodiment of the Coriolis mass flow meter of the invention, the measurement signal is a direct current which is variable, in particular within a range from 4 mA to 20 mA.

According to a further preferred embodiment of the Coriolis mass flow meter of the invention, the measurement signal is a digital signal.

Advantages of the invention and they themselves will now be explained in more detail with reference to the figures of the drawing, in which preferred exemplary embodiments are shown. Parts with the same function are provided with the same reference symbols in the individual figures, but these reference symbols are only repeated in subsequent figures if it appears to be useful. 1 shows, in perspective, mechanical details of a mass flow sensor preferred for use in conjunction with the invention without a completed housing,

FIG. 2 shows a front view of the mass flow sensor corresponding to FIG. 1, again without a completed housing, but with additional electrical details,

Fig. 3 shows in section along the line A-A of Fig. 2 a plan view of Fig. 2, but now with the housing completed,

Fig. 4 shows in section along the line B-B of Fig. 2 a side view of Fig. 2, again with the housing complete,

5 shows, partly in the manner of a block diagram, the circuit diagram of an exemplary embodiment of an excitation circuit in accordance with the first variant of the invention,

6 shows, partly in the manner of a block diagram, the circuit diagram of an exemplary embodiment of an excitation circuit in accordance with the second variant of the invention,

7 shows, in part in the manner of a block diagram, the circuit diagram of an exemplary embodiment of an excitation circuit in accordance with the first variant of the invention,

8 shows a circuit diagram of an exemplary embodiment of a preferred output stage of the excitation circuit according to FIG. 5,

FIG. 9 shows a circuit diagram of an exemplary embodiment of a preferred output stage of the excitation circuit according to FIGS. 6 and

10 shows a circuit diagram of an exemplary embodiment of a preferred output stage of the excitation circuit according to FIG. 7. 1 shows, in perspective, mechanical details of a Coriolis mass flow sensor, which is preferably suitable for the invention and is referred to below as sensor 10 for short. This sensor has already been described in the earlier EP application 00 11 0091.6 dated May 12, 2000, which corresponds to the US patent application 60 / 205,983.

For reasons of better visibility of its internal structure, however, the housing cannot be seen completely in FIG. 1. 2 shows a corresponding front view with additional electrical details.

In contrast, FIGS. 3 and 4 show sectional views belonging to FIG. 2, each with a completed housing. Because of the selected representation in the form of a perspective FIG. 1 together with an elevation, floor plan and side elevation, the following explanation does not deal with one after the other, but rather the figures are discussed together.

The sensor 10 is inserted by the user in the course of a pipe of a given diameter, e.g., not shown for reasons of clarity, through which a liquid, gaseous or vaporous fluid to be measured flows. over flanges. Instead of using flanges, the transducer 10 can also be connected to the above-mentioned pipeline by other known means, e.g. using Triclamp connections or screw connections.

The sensor 10 has a first measuring tube 1 which is bent in a V-shape in a first plane and which is bent symmetrically with respect to a first line of symmetry. A V-shaped second measuring tube 2 is bent symmetrically in a second plane with respect to a second line of symmetry. The measuring tubes 1, 2 are arranged parallel to each other and each formed in one piece.

The measuring tube 1 has a straight inlet piece 11 with an inlet axis lying in the first plane, a straight outlet piece 12 with an outlet axis lying in the first plane and aligned with the inlet axis; this results in a common axis, which is referred to below as the inlet / outlet axis. The measuring tube 2 has a straight inlet piece 21 with an inlet axis lying in the second plane, a straight outlet piece 22 (only visible in FIG. 3) with an outlet axis lying in the second plane and aligned with the inlet axis; this common axis is also referred to below as the inlet / outlet axis.

The measuring tube 1 also has an inlet elbow 13 connected to the inlet piece 11, an outlet elbow 14 connected to the outlet elbow 12, a first straight tube piece 15 connected to the inlet elbow 13, a second straight tube piece 16 connected to the outlet elbow 14 and one to the tube pieces 15 , 16 connected apex 17.

The measuring tube 2 also has an inlet bend 23 connected to the inlet piece 21, an outlet bend 24 connected to the outlet piece 22 (only visible in FIG. 3), a first straight pipe piece 25 connected to the inlet bend 23 and a second one connected to the outlet bend 24 straight pipe section 26 and an apex 27 connected to the pipe sections 25, 26. The bending of the axis of the apex 17 and that of the apex 27 practically correspond to a circular arc.

The inlet pieces 11, 21 are fixed in an inlet distributor piece 18 and the outlet pieces 12, 22 are fixed in an outlet distributor piece 19. These distributor pieces 18, 19 are held by a support frame 30 which is part of a housing 3 (only visible in FIGS. 3 and 4).

The measuring tubes 1, 2 and the distributor pieces 18, 19 consist of stainless steel, whereby for the measuring tubes 1, 2 the stainless steel with the European material number 1.4539, which corresponds to the American designation 904 L, and for the distributor pieces 18, 19 the stainless steel with the European material number 1.4404, which corresponds to the American designation 316 L, is used.

The sensor 10 is to be inserted into a pipeline through which a fluid to be measured flows, at least temporarily. For this purpose, in accordance with the wishes of the buyer of the sensor 10, the manufacturer and the inlet and the outlet manifold 18, 19 attached connecting devices, such as sockets with an external or internal thread, flanges or clamping devices, such as are commercially available, for example, under the registered trademark Triclamp.

Just like the measuring tubes 1, 2, the support frame 30 is formed in one piece and consists of a flat stainless steel of constant width and thickness having a front surface 31 and a rear surface 32 (only to be seen in FIGS. 3 and 4) by appropriate bending and welding of the Ends, cf. the seam 33 has been made.

The support frame 30 comprises a flat inlet frame piece 34, in which the inlet distributor piece 18 is welded, and a flat outlet frame piece 35, in which the outlet distributor piece 19 is welded, cf. 2 the parts of the distributor pieces 18, 19 projecting above the supporting frame 30, each with an associated weld seam 18 ', 19'.

The support frame 30 further comprises a flat passage frame piece 36 connecting the inlet and outlet frame pieces 34, 35, in which an electrical passage 37 (only seen in FIG. 4) is fixed in a pressure-tight manner. The lead-through frame piece 36 forms a right angle with the inlet and outlet frame pieces 34, 35.

The support frame 30 further comprises a flat first attachment frame piece 38, which is attached to the inlet frame piece 34 at an angle and is approximately 120 °. Finally, the support frame 30 comprises a curved apex frame piece 39 which merges into the extension frame piece 38 and a flat second attachment piece 40 which is attached to the outlet frame piece 35 at the aforementioned angle and merges into the apex frame piece 39.

The support frame 30 is supplemented by a flat front plate 41 made of stainless steel welded to the front surface 31 and a flat rear plate 42 made from the same steel welded to the rear surface 32 to form the housing 3, so that it is pressure-tight. Front and rear panels 41, 42 can only be seen in FIGS. 3 and 4. The steel for the housing 3 is the stainless steel with the European one Material number 1.4301 is used, which corresponds to the American designation 304.

The flat front and rear plates 41, 42 result in a higher rigidity of the housing 3 with respect to a pressure load in the direction of the inlet / outlet axis than if these plates were provided with longitudinal beads.

The measuring tubes 1, 2 are rigidly connected to one another by means of a first node plate 51 in the vicinity of a point at which the respective inlet piece 11, 21 merges into the respective inlet bend 13, 23, and rigidly to one another by means of a second node plate 52 in the vicinity of a point connected at which the respective inlet bend 13, 23 merges into the respective first pipe section 15, 25.

The measuring tubes 1, 2 are also rigidly connected to one another by means of a third node plate 53 in the vicinity of a point at which the respective outlet piece 12, 22 merges into the respective outlet bend 14, 24, and rigidly by means of a fourth node plate 54 in the vicinity of a point connected to each other, at which the respective outlet bend 14, 24 merges into the respective second pipe section 16, 26.

The four node plates 51, 52, 53, 54 are thin stainless steel disks as used for the housing 3. These disks are provided with bores, the outer diameter of which corresponds to that of the measuring tubes 1, 2, and with slots, so that the disks can first be clamped onto the measuring tubes 1, 2 and then brazed to them; the slots are also brazed to one another so that the disks are unslotted as node plates on the measuring tubes 1, 2.

An exciter arrangement 6 sets the measuring tubes 1, 2 in operation in tuning fork-like vibrations which, as usual, have an oscillation frequency which is equal to the mechanical resonance frequency of the oscillation system formed by the measuring tubes 1, 2 or which is in the vicinity of this resonance frequency. As is known, this oscillation frequency is dependent on the density of the fluid flowing through the measuring tubes 1, 2 during operation. The density of the fluid can therefore be determined on the basis of the oscillation frequency. As the density depends on the temperature, this is also measured, see below. A first part 61 of the excitation arrangement 6 is fixed to the apex 17 of the measuring tube 1 in the area of its symmetry line mentioned above and a second part 62 of the excitation arrangement 6 is fixed to the apex 27 of the measuring tube 2 in the area of its symmetry line mentioned above, cf. Fig. 4.

The excitation arrangement 6 is an electrodynamic excitation arrangement, and thus the part 61 is a coil arrangement and the part 62 is a permanent magnet arrangement which interacts with the coil arrangement by immersion. The exciter arrangement 6 is supplied by an exciter circuit 20 to be explained with the drive energy required to maintain the vibrations of the measuring tubes 1, 2, in particular at one of their instantaneous resonance frequencies. The excitation circuit 20 can e.g. be housed together with the evaluation circuit already mentioned in an electronics housing (not shown) connected to the flange 90.

A first speed or displacement sensor 7 and a second speed or displacement sensor 8, which are fixed thereon symmetrically with respect to the aforementioned lines of symmetry of the measuring tubes 1, 2, generate sensor signals by means of which the mass flow or e.g. the density of the fluid can also be determined in the usual way.

A first part 71 of the speed or displacement sensor 7 is fixed on the pipe section 15 of the measuring pipe 1 and a second part 72 on the pipe section 25 of the measuring pipe 2, cf. Fig. 3. A first part 81 of the speed or displacement sensor 8 is fixed to the pipe section 16 of the measuring tube 1 and a second part 82 to the pipe section 26 of the measuring tube 2, cf. Fig. 3.

The speed or displacement sensors 7, 8, which are referred to below as sensors 7, 8, are here electrodynamic speed sensors; thus the parts 71, 81 are each a coil arrangement and the parts 72, 82 are each a permanent magnet arrangement which can be immersed in the associated coil arrangement.

As has already been briefly mentioned above, the bushing 37 having a plurality of electrical conductors is fastened in the support frame 30 with respect to the crown arches 17, 27 and thus also with respect to the crown frame piece 39, in particular. used pressure-tight. For this purpose, a flange 90 is fastened to the support frame 30, for example welded. The flange 90 has a bore 91 so that the bushing 37 is accessible from outside the housing 3.

The leadthrough 37 comprises a printed circuit board 96 fastened to the supporting frame 30 by means of an angled supporting plate 95 and tapering between the latter and the apex arches thereon. the interconnect 97, which can only be seen in FIG. 2.

On each of these interconnects there are connecting lines 63, 64 of the excitation arrangement 6, connecting lines 73, 74 of the speed sensor 7, connecting lines 83, 84 of the speed sensor 8 and connecting lines 93, 94 of a temperature sensor 9 and thus also to the single conductor of the implementation 37 connected. The connecting lines 63, 64, 73, 74, 83, 84, 93, 94 can only be seen in FIG. 2. In addition, a conductor track for a circuit zero point SN is also provided on the printed circuit board 96, which is fixed to the metallic support plate 95 by means of metallic, mechanically and therefore also electrically connected fastening means.

The temperature sensor 9 (only seen in Figs. 2 and 3) is on the outlet bend 14 of the measuring tube 1, e.g. fixed by gluing and is e.g. a platinum resistor. As mentioned at the beginning, it is used to measure the instantaneous temperature of the fluid. The temperature sensor 9 can also be arranged at any suitable other point on the measuring tubes 1, 2.

The bushing 37 further comprises a slot 361, which is provided in the bushing frame piece 36, through which the circuit board 96 is inserted and which extends into the flange 90, a sufficient distance being maintained between the circuit board 96 and the slot 361 for its electrical insulation.

Furthermore, the printed circuit board 96 is inserted through a disk 362 made of an insulating material which rests on the bushing frame piece 36 on the bore side. An insulating potting compound 363 completely fills a part of the bore 91 above the disk 362, the potting compound 363 also being able to penetrate more or less into the space between the printed circuit board 96 and the inner wall of the slot 361. The thickness of the casting compound 363 in the direction of the open end of the bore 91 is at least equal to the length of the gap length prescribed for the type of protection Ex-d according to the European standards EN 50 014 and EN 50 018, depending on the gap width. Comparable standards from other countries correspond to these standards.

Instead of the preferred transducer of Figures 1 to 4, other transducers already described in the prior art with at least one curved measuring tube can be used together with the invention, e.g. the transducers described in US-A 53 94 758, US-A 55 57 973, US-A 56 75 093, US-A 57 05 754, US-A 57 96 011 or US-A 62 23 605 , Pickups with at least one straight measuring tube can also be used with the invention, e.g. the transducers described in US-A 47 93 191, US-A 53 51 561, US-A 55 31 126, US-A 56 02 345, US-A 56 16 868, US-A 57 36 653 or US-A 60 06 609.

5 shows the circuit diagram of an exemplary embodiment of the excitation circuit 20 in accordance with the first variant of the invention, partly in the manner of a block diagram. An amplitude demodulation stage pd is one of the sensor signals supplied by the sensors 7, 8 or e.g. also their sum fed. Thus, the amplitude demodulation stage pd is connected on the input side to one of the sensors 7, 8 - in FIG. 5 that is the sensor 7. The amplitude demodulation stage pd serves to continuously determine an oscillation amplitude of the measuring tube vibrations. Furthermore, the amplitude demodulation stage pd serves to output an output signal, e.g. to provide a simple DC signal that represents this detected vibration amplitude. According to a preferred embodiment of the invention, a peak value detector for the input signal is provided in the amplitude demodulation stage pd. Instead of this peak value detector, e.g. a synchronous rectifier can also be used to detect the oscillation amplitude and is clocked by a reference signal which is in phase with the input signal.

A first input of a comparison stage sa is connected to an output of the amplitude demodulation stage pd; a second entrance to the Comparison stage sa is supplied with an adjustable reference signal Sr, which specifies an amplitude of the vibration of the measuring tubes 1, 2. The comparison stage sa determines a deviation of the output signal of the amplitude demodulation stage pd from the reference signal Sr and outputs it as a corresponding output signal. This deviation can be determined and passed on, for example, using a simple difference between the detected and the vibration amplitude inform given by the reference signal Sr of an absolute amplitude error or, for example, also using a quotient of the detected and given vibration amplitude inform of a relative amplitude error.

The input signal of the amplitude demodulation stage pd is fed to a first input of an amplitude modulation stage am and the output signal of the comparison stage sa is fed to a second input. The amplitude modulation stage a serves to modulate the input signal of the amplitude demodulation stage pd with that of the output signal of the comparison stage sa. Here is a sensor signal or the sum of the two sensor signals - or a signal proportional to each, see below. - The carrier signal and an error signal generated by the comparison stage sa the modulation signal, which - at least slowly - is variable. The error signal represents the deviation of the instantaneous vibration amplitude of the measuring tube or the measuring tubes 1, 2 from its or its desired oscillation amplitude represented by the reference signal Sr. Furthermore, the amplitude modulation stage serves to supply a driver signal for the excitation arrangement 6 which carries the drive energy deliver. For this purpose, the amplitude modulation stage has a corresponding power stage ps for amplifying the carrier signal modulated with the modulation signal.

For the purpose of amplitude modulation of the carrier signal with the modulation signal, according to a preferred embodiment of the invention, a multiplier m is provided in the amplitude modulation stage, cf. Fig. 6

6 shows the circuit diagram of an exemplary embodiment of an excitation circuit 20 in accordance with the second variant of the invention, partly in the manner of a block diagram. The embodiment of FIG. 6 differs from that of FIG. 5 in that instead of Amplitude modulation stage is provided on a pulse width modulation stage pwm with a pulse duration modulator pm clocked by an external alternating signal. As shown in FIG. 6, the pulse duration modulator pm is operated at a constant positive first DC voltage + U1 and is at the circuit zero SN.

The input signal of the amplitude demodulation stage pd is fed to a first input of the pulse duration modulator pm - that is the carrier signal input. This first input is thus connected to one of the sensors - in FIG. 6 this is again the sensor 7. A second input of the pulse duration modulator pm - that is the modulation signal input - is supplied with the error signal proportional to the determined amplitude error. The output of the pulse duration modulator pm is in turn connected to the input of an output stage ps ¹ , which on the output side feeds the excitation arrangement 6 with a corresponding driver signal. The driver signal supplied by the output stage ps' is a square-wave signal which is clocked at a signal frequency of the input signal of the amplitude demodulation stage pd and which has a pulse width modulated with the output signal of the comparison stage sa.

7 shows the circuit diagram of another exemplary embodiment of an excitation circuit 20 in accordance with the first variant of the invention, partly in the manner of a block diagram. The embodiment of FIG. 7 differs from that of FIG. 5 in that, instead of its multiplier m, a comparator kk and a DC voltage converter de are provided, which supply at least one switched supply voltage driving a flowing excitation current flowing in the excitation arrangement 6. The amplitude of this supply voltage is in turn dependent on the output signal of the comparison stage sa and is therefore to be regarded as non-constant. Depending on the design of the supply voltage, the excitation current can be bi-polar or uni-polar.

7 supplies a supply voltage with a positive first potential + u and a negative second potential -u, with a control input of the DC voltage converter de serving to set the potentials providing the output signal of the comparison stage sa receives. The amplitude of the supply voltage supplied by the DC voltage converter de is applied to a corresponding output stage ps "of the pulse width modulation stage pwm which serves to feed the excitation arrangement 6. The output stage ps" is also connected on the input side to one output of the comparator kk. The comparator kk is operated at the constant positive first DC voltage + U1 and is at the circuit zero SN. The input signal of the peak value detector pd is fed to an input of the comparator kk. The comparator kk is thus connected on the input side to one of the sensors - in FIG. 7 this is again the sensor 7.

5 to 7 each indicate with dashed lines that instead of one of the sensor signals from sensors 7, 8, their sum can also be fed to peak value detector pd and multiplier m or pulse duration modulator pm or comparator kk; then these sensor signals are to be passed through a summer s.

5 to 7 show further sub-circuits shown in dashed lines, which represent preferred developments of the excitation circuit according to the invention.

In a further development of the excitation circuit 20, a preamplifier vv is provided, which is connected upstream of the peak value detector pd or possibly the synchronous rectifier.

In another development of the excitation circuit 20, an amplifier v is provided which amplifies the output signal of the comparison stage sa before it reaches the amplitude modulation stage on as an error signal. Such an amplifier can be an operational amplifier op, the non-inverting input of which lies at the circuit zero SN, the inverting input of which is connected to the output of the comparison stage sa via a series resistor wv and to the amplifier output via a shunt resistor ws. The operational amplifier op wired in this way can be seen at the top right in FIGS. 5 to 7. In a further preferred development of the excitation circuit 20, an integrating amplifier vi is provided which amplifies and integrates the output signal of the comparison stage sa before it reaches the multiplier m as an error signal. Such an amplifier can be an operational amplifier op ', the non-inverting input of which lies at the circuit zero SN, the inverting input of which is connected to the output of the comparison stage sa via a series resistor wv' and via a series circuit comprising a shunt resistor ws' and a capacitor k to the amplifier Output is connected. The operational amplifier op 'wired in this way can be seen on the right in the middle of FIGS. 5 to 7.

Another development of the excitation circuit 20 consists of a differentiating and integrating amplifier vd, which amplifies, differentiates and integrates the output signal of the comparison stage sa before it reaches the multiplier m as an error signal. Such an amplifier can be an operational amplifier op ", the non-inverting input of which lies at the circuit zero SN, the inverting input of which is connected via a parallel connection of a series resistor wv" and a first capacitor k1 to the output of the comparison stage sa and via a series circuit comprising a shunt resistor ws " and a second capacitor k2 is connected to the amplifier output. The operational amplifier op "wired in this way can be seen at the bottom right in FIGS. 5 to 7.

The arrows in FIGS. 5 to 7 indicate that the respective amplifier v, vi, vd is to be replaced by the dashed square q, which is either between the output of the comparison stage sa and the second input of the amplitude modulation stage on or but lies between the output of the comparison stage sa and the modulation signal input of the pulse width modulation stage pwm.

It is within the scope of the invention that the functions of the individual subcircuits of FIGS. 5 to 7 are implemented by corresponding analog or digital subcircuits, in the latter case, for example, by means of a suitably programmed microprocessor, the signals to be supplied to this previously being transmitted to an analog / digital Conversion and its output signals may have to be subjected to a digital / analog conversion. FIG. 8 shows a circuit diagram of a preferred first exemplary embodiment of an output stage ps, which can be used, for example, in the amplitude modulation stage on according to FIG. 5. An operational amplifier ov is operated on a positive and on a negative, constant DC voltage + U, -U and wired as follows. An inverting input is connected to the circuit zero point SN via a first resistor w1 and a non-inverting input is connected to the output of the multiplier m via a second resistor w2.

An output of the operational amplifier ov is connected to a first pole pp1 of a primary winding of a transformer tf with the interposition of a third resistor w3; a second pole pp2 of the primary winding lies at the circuit zero SN. The transformer tf also has a secondary winding which is connected to the excitation arrangement 6 by means of its two poles sp1, sp2.

The primary winding has a Pπ ^' number of turns N1 and the secondary winding has a number of turns N2. The transformer tf is a current step-up transformer and has a transmission ratio N1 / N2 of, for example, 20: 1.

The inverting input of the operational amplifier ov is connected via a fourth resistor w4 to the first pole pp1 of the primary winding. The non-inverting input is connected to the output via a fifth resistor w5.

The five resistors w1, w2, w3, w4, w5 have corresponding resistance values R1, R2, R3, R4, R5. The resistance value R1 is equal to the resistance value R2 and the resistance value R4 is to be selected equal to the resistance value R5. The alternating current i flowing in the excitation arrangement 6 results as follows if the output voltage of the multiplier m is denoted by um:

^• _ ^R5 M ^{l _ üm '} R1 R3 N2

FIG. 9 shows a circuit diagram of a preferred second exemplary embodiment of an output stage ps', which can be used, for example, in the pulse width modulation stage pwm according to FIG. 6. The "core" of this configuration of the Output stage, which is a complementary push-pull output stage, is a series connection of the controlled current path of a P-channel enhancement insulating layer field-effect transistor P with an N-channel enhancement insulating layer field-effect transistor N, hereinafter referred to briefly as transistors are designated.

The excitation arrangement 6 is connected at the connection point of the controlled current paths. A protective diode dn, dp is connected in parallel to each controlled current path, the respective cathode being located at the more positive point of the respective transistor.

The P-transistor end of the series circuit is connected to a constant positive second DC voltage + U2 and its N-transistor end to a corresponding negative DC voltage -U2. The gates of the transistors N, P are connected to one another and to an output of a comparator kk '. The non-inverting input of the comparator kk 'is at the output of the pulse duration modulator pm, cf. Fig. 6.

The inverting input of the comparator kk 'is connected to a tap of a voltage divider, which consists of a resistor r1 and a resistor r2. The resistors r1, r2 have the same resistance values and lie between the positive DC voltage + U1 and the circuit zero SN. The resistors r1, r2 and the comparator kk 'serve to symmetrize the output signal of the pulse duration modulator pm with respect to half the value of the DC voltage + U1.

The exciter arrangement 6 thus receives a positive current pulse at each positive zero crossing of the output signal from the sensor 7 or the sum of the output signals from the sensors 7, 8 and at each negative direction zero crossing of the output signal from the sensor 7 or the sum of the output signals from the sensors 7, 8 fed a negative current pulse. The respective duration of these current pulses is automatically set such that the oscillation amplitude of the measuring tube or measuring tubes 1, 2 predetermined by the reference signal Sr is reached. FIG. 10 shows a circuit diagram of a preferred third exemplary embodiment of an output stage ps ", which can be used, for example, in the amplitude modulation stage on according to FIG. 7. The" core "of this embodiment of the output stage, which is again a complementary push-pull output stage here, too, as in FIG. 9, a series circuit of the controlled current path of a P-channel enhancement insulating layer field-effect transistor P 'with an N-channel enhancement insulating layer field-effect transistor N ¹ , which is referred to again briefly below as transistors are.

The excitation arrangement 6 is connected at the connection point of the controlled current paths. A protective diode dn ', dp' is connected in parallel to each controlled current path, the respective cathode being located at the more positive point of the respective transistor.

The P-transistor end of the series circuit is connected to the positive DC voltage + u which is dependent on the output signal of the comparison stage sa and the N-transistor end of which is connected to the negative DC voltage -u which is dependent on the output signal of the comparison stage sa. The gates of the transistors N ', P ¹ are connected to one another and to an output of a comparator kk ". The non-inverting input of the comparator kk" is at the output of the comparator kk, cf. Fig. 7.

The inverting input of the comparator kk "is connected to a tap of a voltage divider, which consists of a resistor r3 and a resistor r4. The resistors r3, r4 have the same resistance values and lie between the constant positive first DC voltage + U1 and the circuit zero point SN. The resistors r3, r4 and the comparator kk "serve to symmetrize the output signal of the comparator kk with respect to half the value of the direct voltage + U1.

The exciter arrangement 6 thus receives a positive current pulse during each positive half-wave of the output signal of the sensor 7 or the sum of the output signals of the sensors 7, 8 and one during each negative half-wave of the output signal of the sensor 7 or the sum of the output signals of the sensors 7, 8 negative current pulse supplied. The respective amplitude of these current pulses is different from that of the output signal Comparison stage sa dependent DC voltages + u, -u in turn dependent, so that the oscillation amplitude of the measuring tube or measuring tubes 1, 2 predetermined by the reference signal Sr is set automatically.

The mentioned DC voltages + U1, + U2, -U2 are generated in the usual way on the basis of the energy made available by the two-wire process control loop. It is also possible to provide only one positive DC voltage instead of the two positive DC voltages + U1, + U2.

The two-wire process control loop mentioned in the invention preferably carries on the one hand a direct current which serves for the energy supply, the measuring signal in particular also being a direct current which e.g. standardly covers a range from 4 mA to 20 mA. On the other hand, the measurement signal can also preferably be a digital signal, so that the two-wire process control loop can be connected to a fieldbus.

The excitation circuit of the invention, together with the measuring tube (s) 1, 2, represents a control circuit which is electrically dependent both on the mechanical resonance frequency of the excited vibrations of the measuring tube (s) 1, 2 and on the amplitude of these vibrations predetermined by means of the reference signal Sr. established.

The excitation circuits customary hitherto, which have an amplitude control stage and a phase-locked loop, a so-called PLL, for the electrical control of the resonance frequency and the vibration amplitude are therefore not necessary. The previous excitation circuits are not only very complex in terms of the number of components required, they also require far more supply energy than is available with two-wire measuring devices.

The excitation circuit 20 of the invention requires only a few components, which thus have only a practically negligible power loss, so that the low supply energy available can be used almost completely for excitation.

Claims

1. Excitation circuit for a Coriolis mass flow meter (10) connected to a two-wire process control loop, which is alone supplied with energy and which delivers a measurement signal alone

- at least one measuring tube (1, 2) vibrating during operation,

an electromechanical excitation arrangement (6) for vibrating the at least one measuring tube at an oscillation frequency which is equal to or adjacent to an instantaneous mechanical resonance frequency,

a sensor arrangement (7, 8) reacting to vibrations of the at least one measuring tube (1, 2) for generating a first sensor signal representing vibrations of the measuring tube (1, 2) on the inlet side and a second sensor signal representing vibrations of the measuring tube (1, 2) on the outlet side, which excitation circuit includes:

- An amplitude demodulation stage (pd) for generating an output signal which currently represents an oscillation amplitude of the vibrating measuring tube (1, 2), the amplitude demodulation stage (pd) being supplied with one of the sensor signals supplied by the sensor arrangement (7, 8) or the sum thereof as an input signal is

- A comparison stage (sa) for determining a deviation of the detected vibration amplitude of the vibrating measuring tube (1, 2) from a predetermined desired vibration amplitude, the comparison stage (sa) on the input side being supplied with a reference signal (Sr) in addition to the output signal of the amplitude demodulation stage (pd) , which represents the target vibration amplitude, and

- An amplitude-modulation stage (am) coupled on the input side to an output of the comparison stage (sa) for generating a driver signal for the excitation arrangement (6), which has a signal amplitude dependent on the determined deviation, the amplitude-modulation stage (am) on the input side showing the deviation of the detected one Vibration amplitude of the predetermined target vibration amplitude representing error signal, the input signal of the amplitude demodulation stage (pd) is supplied.

2. Excitation circuit for a Coriolis mass flow meter (10) connected to a two-wire process control loop, which is supplied with energy alone and which emits a measurement signal

- at least one measuring tube (1, 2) vibrating during operation,

an electromechanical excitation arrangement (6) for vibrating the at least one measuring tube at an oscillation frequency which is equal to or adjacent to an instantaneous mechanical resonance frequency,

a sensor arrangement (7, 8) reacting to vibrations of the at least one measuring tube (1, 2) for generating a first sensor signal representing vibrations of the measuring tube (1, 2) on the inlet side and a second sensor signal representing vibrations of the measuring tube (1, 2) on the outlet side, which excitation circuit includes:

- An amplitude demodulation stage (pd) for generating an output signal which currently represents an oscillation amplitude of the vibrating measuring tube (1, 2), the amplitude demodulation stage (pd) being supplied with one of the sensor signals supplied by the sensor arrangement (7, 8) or the sum thereof as an input signal is

- A comparison stage (sa) for determining a deviation of the detected vibration amplitude of the vibrating measuring tube (1, 2) from a predetermined desired vibration amplitude, the comparison stage (sa) on the input side being supplied with a reference signal (Sr) in addition to the output signal of the amplitude demodulation stage (pd) , which represents the target vibration amplitude, and

- A pulse width modulation stage (pwm) coupled on the input side to an output of the comparison stage (sa) for generating a clocked driver signal for the exciter arrangement (6), which has a pulse width dependent on the determined deviation, the pulse width modulation stage (pwm) on the input side along with the deviation of the detected vibration amplitude from the predetermined target vibration amplitude representing error signal, the input signal of the amplitude demodulation stage (pd) is supplied.

3. excitation circuit according to claim 1 or 2, wherein the

Amplitude demodulation stage (pd) comprises a peak value detector for detecting a signal amplitude of the input signal of the amplitude demodulation stage (pd).

4. Excitation circuit according to one of the preceding claims, wherein the amplitude demodulation stage (pd) comprises a preamplifier (vv) for the input signal of the amplitude demodulation stage (pd).

5. Excitation circuit according to one of the preceding claims, in which a proportional, integrating and / or differentially transmitting amplifier (v, vi, vd) is provided in the comparison stage (sa) for generating the error signal.

6. Excitation circuit according to claim 1, wherein the amplitude modulation stage (am) comprises an output stage (ps) with an operational amplifier (ov), which is connected as follows:

an inverting input is connected to a circuit zero point (SN) via a first resistor (w1),

a non-inverting input lies at the output of the multiplier (m) via a second resistor (w2), which has the same resistance value as the first resistor,

- An output is connected with the interposition of a third resistor (w3) with a first pole (pp1) of a primary winding of a transformer (tf), of which a second pole (pp2) is at the circuit zero (SN), which transformer

- Has a secondary winding connected to the electromechanical excitation arrangement (6) and

- is a step-up transformer,

- The inverting input is connected to the output via a fourth resistor (w4), and

- The non-inverting input is connected via a fifth resistor (w5), which has the same resistance value as the fourth resistor, to the first pole (pp1) of the primary winding.

7. Excitation circuit according to claim 1, wherein the amplitude modulation stage (am) comprises a complementary push-pull output stage (ps ") which is fed with a DC supply voltage (+ u, -u) which is dependent on the determined deviation.

8. Coriolis mass flow meter with an excitation circuit according to one of the preceding claims, wherein the two-wire process control loop carries a direct current serving for energy supply.

9. Coriolis mass flow meter according to claim 8, wherein the measurement signal is a, in particular within a range of 4 mA to 20 mA variable, direct current.

10. Coriolis mass flow meter according to claim 8, wherein the measurement signal is a digital signal.