EP0842401A1 - Mass flowmeter - Google Patents

Abstract

The invention relates to a mass flowmeter for flowing media which operates according to the Coriolis principle and has a straight Coriolis measuring tube (2) with a plurality of oscillation generators (3) acting on the Coriolis measuring tube and with transducers (4) detecting a plurality of Coriolis forces and/or Coriolis oscillations caused by Coriolis forces. Said mass flowmeter can also be used to measure the flow of gases with a high level of accuracy. Consequently, the oscillation producers (3) are designed and arranged in such a manner that the Coriolis measuring tube (2) oscillates about its longitudinal axis.

Description

 Mass flow meter

The invention relates to a mass flow meter for flowing media, which works according to the Coriolis principle, with an at least essentially straight Coriolis measuring tube, with at least one vibration generator acting on the Coriolis measuring tube and with at least one Coriolis force and / or Coriolis force-based sensor recording Coriolis vibrations.

Mass flowmeters for flowing media, which work according to the Coriolis principle, are known in various versions (cf., for example, German Patent 41 24 295 and German Laid-Open Application 41 43 361 and those there in columns) 1, lines 20 to 27, the publications listed, the German patent specification 42 24 397 and the publications listed there in column 1, lines 23 to 30, and the German patent application 196 01 342) and have been increasing for some time found in practice.

In the case of mass flowmeters for flowing media which operate according to the Coriolis principle, a distinction is made between on the one hand those whose Coriolis measuring tube is at least essentially straight, generally exactly straight, and on the other hand those whose Coriolis -Measuring tube is loop-shaped. In addition, a distinction is made in the mass flow meters in question between, on the one hand, those which have only one Coriolis measuring tube and, on the other hand, those which have two Coriolis measuring tubes. In the case of the versions with two Coriolis measuring tubes, these can be in flow terms in series or parallel to one another.

Mass flow meters of the type in question, in which the Coriolis measuring tube is straight or the Coriolis measuring tubes are straight, are simple in terms of mechanical construction and consequently can be produced at relatively low cost. The inner surfaces of the Coriolis measuring tube or the Coriolis measuring tubes are also easy to machine; they can be polished easily. Otherwise, they have a relatively low pressure drop. It can be disadvantageous in the case of mass flow measuring devices which operate according to the Coriolis principle and in which the Coriolis measuring tube is straight or the Coriolis measuring tubes are straight.

CONFIRMATION COPY be that thermally induced expansions or stresses as well as forces and moments acting from outside can lead to measurement errors and mechanical damage, namely to stress cracks.

The experts have already dealt with the problems outlined above in the case of mass flow meters with straight Coriolis measuring tubes (cf. in particular the German patent specification 41 24 295, the German patent application specification 41 43 361 and the German patent specification 42 24 379). Overall, various measures have succeeded in creating a mass flow meter with a straight Coriolis measuring tube that works according to the Coriolis principle and has only a measurement error of 0.1% (see the brochure "Approval of the CorimassG device for custody transfer" from KROHNE Meßtechnik GmbH & Co. KG).

Mass flow meters that have only a straight Coriolis measuring tube and work according to the Coriolis principle have considerable advantages over those mass flow meters that have either two straight Coriolis measuring tubes or a loop-shaped Coriolis measuring tube. Compared to mass flow meters with two straight Coriolis measuring tubes, the advantage can be seen primarily in the fact that flow dividers or flow mergers, which are required in mass flow meters with two Coriolis measuring tubes, are not required. Compared to mass flowmeters with a loop-shaped Coriolis measuring tube or with two loop-shaped Coriolis measuring tubes, the advantage can be seen primarily in the fact that a straight Coriolis measuring tube can be manufactured more easily than a loop-shaped Coriolis measuring tube that the pressure drop at a straight Coriolis measuring tube is less than a loop-shaped Coriolis measuring tube and that a straight Coriolis measuring tube can be cleaned better than a loop-shaped Coriolis measuring tube.

Mass flow meters, which work according to the Coriolis principle and have a straight Coriolis measuring tube, also have a physically or mechanically predetermined disadvantage (cf. European laid-open specification 0 521 439):

The mass flow meters working according to the Coriolis principle require that the Coriolis measuring tube is set in vibration, with the aid of at least one vibration generator; from the fact that the Coriolis measuring tube - -

vibrates, and the Coriolis forces or the Coriolis vibrations result from the flow of mass through the Coriolis measuring tube.

In mass flowmeters with two straight Coriolis measuring tubes or with a loop-shaped Coriolis measuring tube or with two loop-shaped Coriolis measuring tubes, the Coriolis measuring tubes or the vibration-effective parts of the loop-shaped Coriolis measuring tubes are designed identically and are arranged and excited in terms of vibration in such a way that they excite one another swing. This has the positive consequence that the vibrating system as a whole does not become effective as such. The position of the center of mass remains constant and any forces that occur are compensated. Consequently, no forces and no vibrations are introduced into the pipeline system in which such a mass flow measuring device is installed, and forces and vibrations of the pipeline system do not influence the measurement result.

In the case of mass flowmeters which operate according to the Coriolis principle and which have only one straight Coriolis measuring tube, the positive consequence of Coriolis measuring tubes which oscillate against one another is of course not given. The center of mass does not remain constant, and any forces that occur are not compensated for. The result of this is that, on the one hand, forces and vibrations are transmitted into the pipeline system in which such a mass flow meter is installed, and that forces and vibrations from the pipeline system and acting on the mass flow meter can also influence the measurement result.

The known mass flowmeters, which have been explained in detail above and work according to the Coriolis principle, are today readily suitable for measuring the flow of liquids with high measuring accuracy, namely with a measuring error of 0.1%. However, they are not equally suitable for measuring the flow of gases. The invention is therefore based on the object of specifying a mass flow meter of the type in question, with which the flow of gases can also be measured with high measuring accuracy. The mass flow meter according to the invention, in which the above-mentioned object is achieved, is initially and essentially characterized in that the vibration generator or the vibration generator is designed and arranged so that the Coriolis measuring tube oscillates about its longitudinal axis. On the one hand, the Coriolis measuring tube can be made with a relatively short length and with a relatively large diameter. This results in low manufacturing costs and a low pressure loss. On the other hand, the oscillation of the Coriolis measuring tube around its longitudinal axis, which is realized according to the invention, means that the mass flow meter according to the invention is relatively insensitive to forces and vibrations which are exerted on the mass flow meter by the piping system in which such a mass flow meter is installed. In fact, the forces and vibrations which are exerted on the mass flow meter by the piping system into which a mass flow meter according to the invention is installed are those which act horizontally, vertically or axially, but not those which act as vibrations around the longitudinal axis of the Coriolis measuring tube. Consequently, forces and vibrations coming from outside practically do not influence the vibrations of the Coriolis measuring tube about its longitudinal axis, so that consequently such forces and vibrations have practically no influence on the measurement result. This again has the consequence that the mass flow meter according to the invention can be designed to be particularly sensitive to measurement, because external influences practically do not influence the measurement result. It then follows from this that the mass flow meter according to the invention is also particularly suitable for gases as the flowing medium, because in such a case the Coriolis forces that occur are relatively low, and consequently a high level of measurement sensitivity is required.

In the mass flow meter according to the invention, the measuring tube, the z. B. made of stainless steel, Hastelloy, titanium or zirconium can be designed very differently in terms of its cross section. In particular, the Coriolis measuring tube can have an elliptical, a circular, a rectangular, that is to say also a square, or an approximately eight-shaped cross section.

In the mass flow meter according to the invention, the cross section of the Coriolis measuring tube - viewed over its length - does not have to be constant, but rather can the Coriolis measuring tube - seen over its length - have different cross-sections and / or cross-sectional shapes. In particular, it can be advantageous if the Coriolis measuring tube has a circular cross section at both ends and an elliptical cross section in the middle. The transition from the circular cross sections at the ends to the elliptical cross section in the middle is of course continuous.

It is essential for the teaching of the invention that the vibration generator or - as a rule - the vibration generator is designed and arranged so that the Coriolis measuring tube oscillates about its longitudinal axis. This leaves the designer a variety of options for the execution and arrangement of the vibration generator or the vibration generator in detail. In particular, as is known in the prior art, electromagnetic or piezoelectric vibration generators can be used. In any case, it is advisable to arrange the vibration generator (s) over the length of the Coriolis measuring tube in the middle of the Coriolis measuring tube, so that the vibration of the vibration generator or the vibration generators Coriolis measuring tube is symmetrical about its longitudinal axis to the center of the Coriolis measuring tube. The same result is of course achieved if a vibration generator or vibration generator is provided on both sides with a symmetrical distance from the center of the Coriolis measuring tube.

In the case of mass flowmeters which operate according to the Coriolis principle and which are customary vibration generators, namely both electromagnetic and piezoelectric vibration generators, initially produce a back and forth movement. In order to allow the oscillation generator or the oscillation generator to produce what is desired according to the invention, namely oscillation of the Coriolis measuring tube about its longitudinal axis, there are various possibilities. A preferred embodiment of the mass flow meter according to the invention in this regard is characterized in that two vibration generators are provided and the two vibration generators, preferably offset by 180 °, act tangentially on the Coriolis measuring tube. Instead of providing only two vibration generators, it is also possible to provide a larger number of vibration generators, for example four vibration generators can be provided, in which case the vibration generators, preferably offset by 90 °, act tangentially on the Coriolis measuring tube. In the same sense means that all vibration generators at the same time, for. B. clockwise and counterclockwise at the same time are effective.

According to a further teaching of the invention, which is of particular importance, a preferred embodiment of the mass flow meter according to the invention is characterized in that four vibration generators are provided, that the vibration generators attack the Coriolis measuring tube, preferably offset by 90 °, that two act by 180 ° offset vibration generators tangentially opposite and the other two vibration generators, offset from each other by 180 ° and offset from the first two vibration generators by 90 ° each, act radially on the Coriolis measuring tube in the same direction and that the forces exerted by the first two vibration generators act in opposite directions to those forces exerted by the other vibrators are directed. It is thereby achieved that at any moment the sum of the forces exerted by the vibration generators on the Coriolis measuring tube - and of course also the sum of all reaction forces - is zero, and on the other hand the position of the center of mass of the Coriolis measuring tube - and beyond the position of the center of mass of the mass flow meter according to the invention overall remains constant. The most important consequence of this is that the mass flow meter thus constructed is free from the disadvantages described at the outset, which are actually inherent to mass flow meters which operate according to the Coriolis principle and have only a straight Coriolis measuring tube.

According to a further teaching of the invention, which in turn has considerable special significance, a special embodiment of the mass flow meter according to the invention is characterized in that on the inside of the Coriolis measuring tube extending - as it were fin-like - webs extending in the longitudinal direction of the Coriolis measuring tube are, preferably two, three or four webs, possibly even more webs, the webs being expediently arranged uniformly distributed over the circumference of the Coriolis measuring tube. The Coriolis forces occurring act on the webs provided on the inside of the Coriolis measuring tube and thus on the Coriolis measuring tube. In all the previously described embodiments of mass flowmeters according to the invention, the designer has extensive freedom with regard to the design and arrangement of the sensors. The transducers, as known in the art, as well as the vibration generator, for. B. be carried out electromagnetically or piezoelectrically.

In addition, it is advisable to provide two transducers and to arrange the two transducers symmetrically to the center of the Coriolis measuring tube, as seen over the length of the Coriolis measuring tube. Of course, there is also the possibility of providing more than two transducers, namely — seen over the length of the Coriolis measuring tube — symmetrically to the center of the Coriolis measuring tube, in each case providing several transducers and arranging the transducers evenly distributed over the circumference of the Coriolis measuring tube .

So far it has been stated that for the mass flow meter in question, a straight Coriolis measuring tube, at least one vibration generator acting on the Coriolis measuring tube and at least one Coriolis force and / or Coriolis vibrations based on Coriolis forces detecting transducer ge heard. As is known in the prior art, the Coriolis measuring tube can also be arranged concentrically within a preferably circular cylindrical bridge in the mass flow meter according to the invention. It is then advisable to arrange the oscillation generator or the oscillation generators and the measurement transducer or the measurement transducers between the Coriolis measuring tube and the bridge, so that the oscillation generator or the oscillation generators and the measurement transducer or the measurement transducers between the Coriolis measuring tube and the bridge are effective.

Finally, it is also advisable in the case of the mass flow meter according to the invention, as is known in the prior art, to provide at least one temperature sensor for compensating for thermal influences on the measuring accuracy and / or the zero point. Belongs to the mass flow meter according to the invention, as described above, a bridge accommodating the Coriolis measuring tube, so recommends it is possible to provide both the Coriolis measuring tube and the bridge with a temperature sensor.

In particular, there are now a multitude of possibilities for designing and developing the mass flow meter according to the invention. For this purpose, reference is made on the one hand to the claims subordinate to claim 1, and on the other hand to the description of preferred exemplary embodiments in conjunction with the drawing. The drawing shows, each schematically,

Fig. 1 is a graphical representation for a general explanation of the teaching of

Invention,

Fig. 2 shows a preferred embodiment of a to an inventive

Mass flow meter belonging to Coriolis measuring tube,

3 shows a longitudinal section through a first exemplary embodiment of a mass flow meter according to the invention,

4 shows a longitudinal section through a second exemplary embodiment of a mass flow meter according to the invention,

5 shows a cross section through a preferred exemplary embodiment of a mass flow meter according to the invention,

Fig. 6 is a graphical representation to explain another teaching of

Invention,

7 shows a graphical representation to explain the Coriolis forces occurring in the teaching of the invention according to FIG. 6, FIG.

8 is a graphical representation corresponding to FIG. 7, 9 is a graphical representation corresponding to FIGS. 1 and 6 to explain a further exemplary embodiment of a mass flow measuring device according to the invention,

10 shows cross sections through differently designed embodiments of a further exemplary embodiment of a mass flow meter according to the invention,

Fig. 1 1 is a perspective view belonging to Fig. 10 and

Fig. 12 is a graph showing the embodiment of a mass flow meter according to the invention, which is shown in Figs. 10 and 11.

The mass flow meter according to the invention for flowing media, in particular for gases, is one that works according to the Coriolis principle. The mass flow measuring device according to the invention initially includes, as a rule, but not functionally required, a housing 1 indicated only in FIGS. 3 and 4. Functionally necessary, the mass flow measuring device according to the invention includes an at least essentially, as a rule and in the exemplary embodiments shown exactly straight Coriolis measuring tube 2, at least one vibration generator 3 acting on the Coriolis measuring tube 2 and at least one Coriolis forces and / or Coriolis vibrations based on Coriolis forces are recorded by the measuring transducer 4, as a rule two transducers 4.

According to the invention, the vibration generators 3 are initially designed and arranged in such a way that the Coriolis measuring tube 2 oscillates about its longitudinal axis.

1, 5 and 6 in particular that the Coriolis measuring tube 2 can have an elliptical cross section. In the exemplary embodiment indicated in FIG. 9, the Coriolis measuring tube 2 has an approximately eight-shaped cross section. As shown in FIG. 9, this is not strictly an eight-shaped cross section. The cross-section shown here can also be referred to as a double-circular cross-section, two circular partial cross-sections through a neck like middle part are connected. For the exemplary embodiment to which FIGS. 10, 11 and 12 belong, the Coriolis measuring tube 2 has a circular cross section.

2 and 4 that the Coriolis measuring tube 2 — viewed over its length — can have different cross sections or different cross sectional shapes. In both exemplary embodiments, the Coriolis measuring tube 2 has a circular cross-section at its two ends and an elliptical cross-section in the middle, the transition from the circular cross-section at the two ends to the elliptical cross-section as shown in FIG. 2 in particular cut in the middle is continuous.

In the upper part a) of FIG. 1, arrows indicate that the Coriolis measuring tube 2 swings about its longitudinal axis, on the one hand counterclockwise, and on the other hand clockwise. The end of the Coriolis measuring tube 2 on the inlet side is shown, the center of the Coriolis measuring tube 2 in the middle, and the end of the Coriolis measuring tube 2 on the outlet side is shown on the right. This also applies to parts b) and c) of FIG. 1.

Arrows in the middle part b) of FIG. 1 indicate how the Coriolis forces that occur affect a medium flowing through the Coriolis measuring tube 2. The effects at the outlet-side end of the Coriolis measuring tube 2 are opposite to the effects at the inlet-side end of the Coriolis measuring tube 2. Coriolis forces do not occur in the center of the Coriolis measuring tube 2.

The lower part c) of FIG. 1 shows by arrows on the one hand the oscillation of the Coriolis measuring tube 2 about its longitudinal axis, and on the other hand the effects of the Coriolis forces that occur.

For the exemplary embodiments of mass flow meters according to the invention, to which FIGS. 3, 4 and 5 belong, it applies that two vibration generators 3 are provided and the two vibration generators 3 are offset tangentially on the Coriolis measuring tube 2 by 180 °. There is also the option of more than two Vibration generator 3 to be provided, for example four vibration generators 3, which then act offset tangentially 90 ° in the same direction on the Coriolis measuring tube 2.

In the embodiment of a mass flow meter according to the invention, to which FIGS. 6, 7 and 8 belong, a further teaching of the invention is realized, which is of very special importance. For this exemplary embodiment it is true that four oscillation generators 3 are provided, that the oscillation generators 3 act offset by 90 ° on the Coriolis measuring tube 2, namely that two oscillation generators 3a arranged offset by 180 ° in opposite directions tangentially and the two other vibration generators 3b, offset from one another by 180 ° and offset by 90 ° in relation to the first two vibration generators 3a, act radially on the Coriolis measuring tube 2 in the same direction and that the forces exerted by the first two vibration generators 3a are opposite to those of the other vibration generators 3b applied forces are directed. It is thereby achieved that, on the one hand, the sum of the forces exerted by the vibration generators 3a and 3b on the Coriolis measuring tube 2 - and of course also the sum of all reaction forces - is zero, and on the other hand the position of the center of mass of the Coriolis -Measuring tube 2 - and also the position of the center of mass of the mass flow meter according to the invention as a whole - remains constant. The extremely positive consequence of this is that the mass flow meter thus constructed is free from the disadvantages described at the outset which are actually peculiar to mass flow meters which operate according to the Coriolis principle and have only a straight Coriolis measuring tube 2.

In FIGS. 7 and 8, arrows indicate how the Coriolis forces affect the Coriolis measuring tube 2 when vibration generators 3a and 3b act on the Coriolis measuring tube 2, as shown in FIG. 6 .

Only for the sake of good order, it should be pointed out that in FIGS. 6, 7 and 8 the deformations of the Coriolis measuring tube 2 which are caused by the vibration generators 3a and 3b on the one hand and the deformations of the Coriolis tube 2 which are caused by the Coriolis forces which occur on the other hand are greatly exaggerated. 10, 11 and 12 show an embodiment of a mass flow meter according to the invention, which is additionally characterized in that on the inside of the Coriolis measuring tube 2 extending in the longitudinal direction of the Coriolis measuring tube 2 - as it were fin-like - webs 5 are provided, namely three webs 5 in the left part of FIG. 10, four webs 5 in the right part of FIG. 10 and two webs 5 in the middle part of FIG. 10 and in FIGS. 1 1 and 12. The Web 5, as shown in FIGS. 10, 1 1 and 12, arranged evenly distributed over the circumference of the Coriolis measuring tube 2. The Coriolis forces that occur act, as indicated in FIG. 12, on the webs 5 provided on the inside of the Coriolis measuring tube 2 and thus on the Coriolis measuring tube 2 as a whole.

With regard to the measuring transducers 4 provided in the mass flow measuring devices according to the invention, the designer has extensive freedom, both with regard to the design and with regard to the arrangement of the measuring transducers 4. In particular, as known in the prior art, the measuring transducers 4 as well as the vibration generator 3, e.g. B. electromagnetic or piezoelectric.

3 and 4 indicate that four transducers 4 are provided. The transducers 4 are - seen over the length of the Coriolis measuring tube 2, symmetrical to the center of the Coriolis measuring tube 2, otherwise evenly distributed over the circumference of the Coriolis measuring tube 2.

Finally, FIGS. 3 and 4 show exemplary embodiments of mass flow measuring devices according to the invention in which the Coriolis measuring tube 2 is arranged concentrically within a circular-cylindrical bridge 6. In this embodiment, the vibration generators 3 and the transducers 4 are then effective between the Coriolis measuring tube 2 and the bridge 6.

Finally, it is not shown in the figures that at least one temperature sensor, preferably both the Coriolis measuring tube 2 and the bridge 6 with an egg, can be provided in the case of mass flow meters according to the invention for compensating for thermal influences on the measuring accuracy and / or the zero point ¬ Nem temperature sensor are provided.

Claims

Claims:

1. Mass flow meter for flowing media, which works on the Coriolis principle, with an at least substantially straight Coriolis measuring tube. with at least one vibration generator acting on the Coriolis measuring tube and with at least one Coriolis forces and / or Coriolis vibrations measuring transducers based on Coriolis forces, characterized in that the vibration generator or the vibration generator (3) is so designed and specified ¬ is or are that the Coriolis measuring tube (2) swings about its longitudinal axis.

2. Mass flow meter according to claim 1, characterized in that the Coriolis measuring tube (2) has an elliptical, a circular, a rectangular or an approximately eight-shaped cross section.

3. Mass flow meter according to claim 1 or 2, characterized in that the Coriolis measuring tube (2) - seen over its length - has different cross sections and / or cross-sectional shapes.

4. Mass flow meter according to claim 3, characterized in that the Coriolis measuring tube (2) has a circular cross section at both ends and an elliptical cross section in the middle.

5. mass flow meter according to one of claims 1 to 4, characterized gekenn¬ characterized in that the vibration generator or the vibration generator (3) - seen over the length of the Coriolis measuring tube (2) - arranged in the center of the Coriolis measuring tube (2) is or are.

6. mass flow meter according to one of claims 1 to 5, characterized gekenn¬ characterized in that two vibration generators (3) are provided and that the two vibration generators (3) offset by preferably 180 ° offset tangentially in the same direction tangentially on the Coriolis measuring tube (2).

7. Mass flow meter according to one of claims 1 to 5, characterized gekenn¬ characterized in that four vibration generators (3) are provided and the vibration Attack the generator (3), preferably offset by 90 °, tangentially on the Coriolis measuring tube (2).

8. Mass flow meter according to one of claims 1 to 5, characterized gekenn¬ characterized in that four vibration generators (3) are provided that the Schwingungs¬ generator (3) offset on the Coriolis measuring tube (2) attack that two 180 ° against each other other offset vibration generators (3a) tangentially opposite and the other two vibration generators (3b), offset from each other by 180 ° and offset from the first two vibration generators (3a) by 90 °, attack radially in the same direction on the Coriolis measuring tube (2) and that the forces exerted by the two first vibration generators (3a) are directed in the opposite direction to the forces exerted by the other vibration generators (3b).

9. Mass flow meter according to one of claims 1 to 8, characterized gekenn¬ characterized in that on the inside of the Coriolis measuring tube (2) extending in the longitudinal direction of the Coriolis measuring tube (2) - fin-like - webs (5) are provided, vor¬ preferably two, three or four webs (5).

10. Mass flow meter according to claim 9, characterized in that the webs (5) are evenly distributed over the circumference of the Coriolis measuring tube (2) angeord¬ net.

1 1. Mass flow meter according to one of claims 1 to 10, characterized gekenn¬ characterized in that two transducers (4) are provided and the two transducers (4) - seen over the length of the Coriolis measuring tube (2) - symmetrical to the center of the Coriolis measuring tube (2) are arranged.

12. Mass flow meter according to one of claims 1 to 10, characterized gekenn¬ characterized in that - seen over the length of the Coriolis measuring tube (2) - symmetrically to the center of the Coriolis measuring tube (2) a plurality of transducers (4) are provided.

13. Mass flow meter according to claim 12, characterized in that the transducers (4) are arranged evenly distributed over the circumference of the Coriolis measuring tube (2).

14. Mass flow meter according to one of claims 1 to 13, characterized gekenn¬ characterized in that the Coriolis measuring tube (2) is arranged concentrically within a preferably circular cylindrical bridge (6).

15. Mass flow meter according to claim 14, characterized in that the vibration generator or the vibration generator (3) and the Meßwerttaufneh¬ mer or the transducer (4) between the Coriolis measuring tube (2) and the bridge (6) are effective.

16. Mass flow meter according to one of claims 1 to 15, characterized gekenn¬ characterized in that at least one temperature sensor is provided to compensate for thermal influences on the measuring accuracy and / or the zero point.

17. Mass flow meter according to claim 14 or 15 and according to claim 16, da¬ characterized in that both the Coriolis measuring tube (2) and the bridge (6) are provided with a temperature sensor.