DE102015107769A1 - Coriolis mass flowmeter or density meter - Google Patents

Abstract

A Coriolis mass flowmeter or density meter (100) comprises two curved measuring tubes (110a, 110b), which extend mirror-symmetrically to a first mirror plane between the measuring tubes, an actuator arrangement (140) and at least one sensor arrangement (142a, 142b); inlet side and outlet side in each case a collector (120a, 120a), with which the measuring tubes are summarized fluidically, wherein the collector (120a, 120b) fulfill the functionality of a node plate; a support body (124) rigidly connecting the collectors (120a, 120b) to each other; and inlet side and outlet side in each case at least one plate-shaped coupler (132a, 132b, 134a, 134b), which connect the measuring tubes in pairs to form an oscillator, wherein the coupler tube openings for the measuring tubes, wherein the measuring tubes at least partially connected to the couplers wherein at least one coupler (132a, 132b, 134a, 134b) is provided on the inlet side and outlet side, between the measuring tubes (110a, 110b), having a tuning opening (146) for influencing the oscillation characteristics of the oscillator.

Description

The present invention relates to a Coriolis mass flowmeter or density measuring device (hereinafter referred to as CMD) with at least two measuring tubes running in the rest position, at least one actuator arrangement and at least one sensor arrangement;
inlet side and outlet side in each case a collector, wherein the measuring tubes are each merged on the inlet side and outlet side with a collector, wherein the inlet side and outlet side collector are designed so stable that they each fulfill the function of a node plate; a support body which rigidly connects the inlet side header and the outlet side header with each other; and inlet side and outlet side in each case at least one, in particular two or more couplers, wherein the measuring tubes are connected in pairs by means of the coupler to form an oscillator, wherein the couplers are arranged in the direction of the Meßrohrachsen each other and to the collector spaced, the couplers respectively two tube openings for the measuring tubes connected by the coupler, through which the measuring tubes are guided, wherein the measuring tubes are at least partially connected along their circumference to the couplers, wherein the actuator assembly is adapted to stimulate a Bieschwwingungsutz wear between the two measuring tubes of the oscillator, the Sensor arrangement is adapted to detect oscillations of the oscillator.

The resonant frequency of this Biegeschwingungsnutzmodes is a measure of the density of the measuring tubes flowing through medium. The phase difference between the two sensor signals of the sensor arrangement is dependent on the mass flow.

Generic CMD are, for example, in DE 10 2011 006 971 A1 , in DE 10 2011 006 919 A1 , in US 2013/0319134 A1 , in US 8,281,668 B2 and in US Pat. No. 6,415,668 B1 as in US 5,370,002 and US 2015/0033874 A1 disclosed. In general, the couplers serve to form an oscillator with defined oscillation properties by the coupling of the measuring tubes.

Investigations of generic CMD in connection with the present invention have shown that the vibrations of their oscillators still dissipate vibration energy to the environment, in particular a connected fluid line. Conversely, interfering oscillations can be coupled into the oscillator in the same way. Both effects can significantly affect the performance of a CMD.

It is therefore the object of the present invention to provide a CMD in which the above disturbing effects are alleviated or avoided.

The CMD according to the invention comprises at least two measuring tubes extending in the rest position, the measuring tubes having measuring tube axes which run mirror-symmetrically to a first mirror plane which extends between the measuring tubes, at least one actuator arrangement and at least one sensor arrangement;
inlet side and outlet side in each case a collector, wherein the measuring tubes are each merged on the inlet side and outlet side with a collector, wherein the inlet side and outlet side collector are designed so stable that they fulfill the functionality of a node plate; a support body which rigidly connects the inlet side header and the outlet side header with each other; and inlet side and outlet side in each case at least one, preferably two or more plate-shaped couplers, wherein the measuring tubes are connected in pairs by means of the coupler to form an oscillator, wherein the couplers each have two tube openings for the connected by the coupler measuring tubes through which the Measuring tubes are guided, wherein the measuring tubes are at least partially connected along their circumference with the couplers, wherein the actuator assembly is adapted to excite a Bieschwwingungsnutzmode between the two measuring tubes of the oscillator, the sensor arrangement is adapted to detect oscillations of the oscillator, wherein the inlet side and each having at least one coupler on the outlet side, between the connected by the coupler measuring tubes surrounded by a closed edge tuning opening for influencing the vibration characteristics of the oscillator. The closed edge extends in particular in the plane of the plate-shaped coupler.

The couplers are arranged on the inlet and outlet side spaced from the collector.

If several couplers are present on the inlet and outlet side, they are arranged at a distance from one another in the direction of the measuring tube axes.

By means of suitable positioning of the plate-shaped couplers, the cross-sensitivity to vibrations from the environment or the dissipation of vibrational energy to the environment, in particular to a connected fluid line can already be reduced to a certain extent. However, since there are various interaction mechanisms that include forces on the one hand and moments that act on the intake and exhaust manifolds on the other hand, Both can not be optimally minimized via just one control parameter, such as the position of the coupler. Here, the voice openings offer additional degrees of freedom with which the interfering interaction mechanisms can be largely eliminated.

In one development of the invention, the voice openings in the first mirror plane have an extent of at least 30%, for example at least 50%, and in particular at least 75% of the diameter of the measuring tubes.

In a further development of the invention, the voice openings in the first mirror plane have a length whose square is not less than twice, for example, not less than four times and in particular not less than eight times the area of the voice opening.

In a development of the invention, the distance of the measuring tube axes at the position of the vocal opening is not more than 1.5 outer diameter of the measuring tubes, in particular not more than 1.3 outer diameter and preferably not more than 1.2 outer diameter.

In one development of the invention, at least one coupler in the respective coupler plane has a convex envelope whose area is not more than five times, in particular not more than four and a half times, in particular not more than four times the outer area of a measuring tube cross section.

In one development of the invention, at least two couplers of a measuring tube pair connected by the coupler have such a voice opening on the inlet side and outlet side.

In a further development of the invention, at least the two inner couplers of a measuring tube pair connected by the coupler have such a voice opening on the inlet side and outlet side, the two inner couplers being the couplers furthest from the respective collector.

In a further development of the invention, the at least one voice opening is substantially symmetrical to the first mirror plane.

In one development of the invention, the vocal opening of at least one coupler is asymmetrical with respect to a second coupler-normal coupler normal plane, the coupler normal plane extending parallel to the largest main axis of inertia of the coupler, perpendicular to the first mirror plane, and a connecting line of the test tube axes perpendicular to the first mirror plane touched within the vocal opening.

In a development of the invention, the distance of the outermost extent of the at least one voice opening in the first mirror plane from the coupler normal plane to a first side of the coupler normal plane is less than on a second side of the coupler normal plane.

In one development of the invention, the distance between the outermost extent of the voice opening in the first mirror plane and the outermost extent of the coupler in the first mirror plane is lower on a first side of the coupler normal plane than on a second side of the coupler normal plane.

In a further development of the invention, at least one coupler on the inlet side and on the outlet side has a center of gravity which is a distance away from the coupler normal plane, the distance being for example not less than 4%, in particular not less than 8% of the distance of the measuring tube axes in the coupler normal plane is.

In a further development of the invention, at least one coupler on the inlet side and on the outlet side has a centroid of a minimum convex envelope which is distant from a coupler normal plane by a distance, the distance being for example not less than 4%, in particular not less than 8% of the distance of Measuring tube axes in the coupler normal plane is.

In a further development of the invention, the inlet side and the outlet side each have one first coupler and a second coupler coupler-specific Kopplernormalenebenen, each extending parallel to the largest main axis of inertia of the respective coupler, which are perpendicular to the first mirror plane, and which extend perpendicular to the first mirror plane connecting line of the Meßrohrachsen within the vocal aperture of the respective coupler, wherein the first The coupler has a first center of gravity spaced from its coupler-specific coupler normal plane by a second distance, the second coupler having a first center of mass spaced from its coupler-specific coupler normal plane by a second distance, the first distance deviating from the second distance the deviation is, for example, not less than 5%, in particular not less than 10% of the smaller of the two distances.

In one development of the invention, inlet and outlet sides each have a first coupler and a second coupler coupler-specific Kopplernormalenebenen each extending parallel to the largest main axis of inertia of the respective coupler, which extend perpendicular to the first mirror plane, and extending perpendicular to the first mirror plane connecting line of Messrohrachsen within the vocal aperture of the respective coupler, with a first coupler having a first centroid of a minimum convex envelope and a second coupler having a second centroid of a minimum convex envelope on the inlet and output sides, the first centroid being away from its coupler specific coupler normal plane by a first distance spaced second center of gravity spaced from its coupler-specific coupler normal plane by a second distance, wherein the first deviation from the second distance, wherein the deviation is for example not less than 5%, in particular not less than 10% of the smaller of the two distances.

In one development of the invention, inlet and outlet sides each have a first coupler and a second coupler coupler-specific Kopplernormalenebenen each extending parallel to the largest main axis of inertia of the respective coupler, which extend perpendicular to the first mirror plane, and extending perpendicular to the first mirror plane connecting line of Messrohrachsen within the vocal aperture of the respective coupler, the first coupler having a first vocal aperture, the second coupler having a second vocal aperture, and wherein the first vocal aperture differs from the second vocal aperture in at least one of the following parameters: area of the vocal aperture, length of the vocal aperture Voice opening, distance of the center of gravity of the voice opening to the respective coupler normal plane.

The above-described symmetry deviations of the plate-shaped couplers and the voice openings are further degrees of freedom, which are used to optimize the oscillator properties, wherein, as mentioned above, the minimization of the cross-sensitivities to vibrations from the environment are at the center of attention. The above-mentioned symmetry deviations also make it possible to minimize the mechanical stresses which occur at the oscillator, in particular at the measuring tubes and the couplers, which in turn contributes to the long-term stability and thus to the reproducibility of the measured values.

In one development of the invention, at least one tuning opening is bounded on the inlet side and outlet side by edge sections, which are formed on both sides by the measuring tubes in a section between the measuring tubes.

In a further development of the invention, the edge sections formed by the measuring tubes each have a length perpendicular to the largest main axis of inertia of the respective coupler which is not less than 10%, in particular not less than 20% and preferably not less than 30% of the radius of the measuring tube, which forms the respective edge portion of the vocal opening

In fact, in conventional couplers in the region between the measuring tubes voltage maxima occur. When the measuring tubes are there with the couplers. If the measuring tubes now according to the embodiment of the invention form an edge portion of the vocal opening, this means that they have a free circumferential surface in this edge portion, whereby the mechanical stress peaks in this area are considerably reduced.

The couplers of the CMD according to the invention make it possible to suppress the decoupling of oscillation energy from the CMD or the coupling of disturbing vibrations from a pipeline into which the CMD is installed. This suppression is particularly effective when the inlet side and the outlet side each two couplers are provided with voice openings. In particular, when the couplers are designed sufficiently rigid, the transmission of such vibration components is suppressed by the measuring tubes to the collectors, which, however, due to symmetry effects only slightly contribute to the coupling of vibrational energy, but still oscillating voltages at the connections between the measuring tubes and cause the collectors. Such oscillating voltages could cause long-term damage to the compounds mentioned, which is associated with a risk of leakage. In this respect, the CMD according to the invention also has a reduced risk of failure due to leakage due to the minimization of these oscillating stresses. For a given material thickness and voice opening length, a sufficiently high stiffness of the couplers can be achieved by a small vocal tract opening area.

In a development of the invention, the plate-shaped couplers have a material thickness which is not more than four times, in particular not more than three times, the wall thickness of the measuring tubes.

The measuring tubes have, according to a development of the invention also a metallic material, in particular stainless steel. The couplers and / or collectors each include one in terms of coefficients of thermal expansion compatible material, in particular the same metallic material.

The CMD according to the invention may comprise one pair, two pairs or more pairs of coupled measuring tubes, in particular each pair being designed by the coupled measuring tubes of the CMD as described above for a measuring tube pair.

In one development of the invention, the CMD on the inlet side and on the outlet side each have a collector in which the measuring tubes of two pairs of measuring tubes of the CMD are combined fluidically.

In a development of the invention, the first mirror plane of the first measuring tube pair is at the same time the first mirror plane of a second measuring tube pair of the CMD according to the invention.

The invention will be explained with reference to the embodiments illustrated in the drawings. Show it:

1a to 1c : Sketches of one for explaining some geometric terms to describe the invention;

1d A coordinate system for describing the invention

2a a schematic representation of a detail of a CMD, for explaining the problem of the present invention;

2 B FIG. 4 is a schematic diagram for explaining the influence of a coupler position on a target function of the CMD design; FIG.

2c FIG. 4 is a schematic diagram for explaining the influence of the voice opening length on an objective function of the CMD design; FIG.

3a a first embodiment of a coupler of a CMD according to the invention;

3b a second embodiment of a coupler of a CMD according to the invention;

3c a third embodiment of a coupler of a CMD according to the invention;

3d A fourth embodiment of a coupler of a CMD according to the invention;

3e A fifth embodiment of a coupler of a CMD according to the invention;

4a : Simulation results of the mechanical stress distributions in the couplers of a CMD according to the prior art;

4b : Simulation results of the mechanical stress distributions in the couplers of a first embodiment of a CMD according to the invention;

4c : Simulation results of the mechanical stress distributions in the couplers of a second embodiment of a CMD according to the invention;

4d : Simulation results of the mechanical stress distributions in the measuring tubes of a CMD according to the prior art;

4e : Simulation results of the mechanical stress distributions in the measuring tubes of an embodiment of a CMD according to the invention;

5a a simplified overall perspective view of an embodiment of a CMD according to the invention;

5b : a detail of the view 5a ; and

5c a simplified side view of the embodiment of a CMD according to the invention from 5a and 5b ,

First, some of the geometric terms used in the following will be explained with reference to FIG 1a . 1b . 1c and 1d explained.

In 1a is a plan view of a section of two parallel measuring tubes 10a . 10b a CMD. A corresponding cross-sectional view taken along the line BB 1a is in 1b shown while 1c a longitudinal section through one of the measuring tubes 10a off along the CC line 1a represents. The measuring tubes 10a . 10b each have a measuring tube axis 12a . 12b which are defined along the course of the measuring tubes in each case by the centers of tube cross-sections of minimum cross-sectional area. The measuring tube axes run symmetrically to a first mirror plane Syz, between the Meßrohrachsen 12a . 12b runs.

Every measuring axis 10a . 10b itself extends symmetrically to a second mirror plane Sxy, which is perpendicular to the first mirror plane Syz. The intersection line between the first mirror plane Syz and the second mirror plane defines the Y axis of a coordinate system for describing the CMD. A third level szx runs perpendicular to the first and second mirror plane. In a two-pipe CMD with curved measuring tubes, this plane is not a mirror plane. As such, the determination of the position of the third plane, which sets the origin of the Y-axis, is arbitrary. The CMD according to the invention each have on the inlet side and outlet side a collector, which usually comprises a process connection flange with a substantially axially symmetrical connection surface whose axis of symmetry coincides with the Z axis. The third plane Szx intersects the first mirror plane Syz along the Z axis. Accordingly, the third plane Szx intersects the second mirror plane Sxy along the X axis.

The measuring tubes 10a . 10b According to the invention are connected in pairs by plate-shaped coupler, which in 1a to 1c are not shown. The respective maximum principal axis of inertia of a coupler, ie those with the largest moment of inertia, runs perpendicular to a coupler plane 14 , in which the center of mass of the coupler lies. The coupler level 14 may be a normal plane to the measuring tube axes, but this is not mandatory. The maximum principal axis of inertia runs parallel to the first mirror plane Syz and lies in particular in the first mirror plane.

Perpendicular to the first mirror plane Syz and perpendicular to the coupler plane 14 runs a coupler-specific coupler default level 16 in which the coupler plane 14 and a connecting line of the measuring tube axes 12a . 12b fall together.

The excitation of the measuring tubes is usually in the X direction, in particular with an actuator, which is arranged in the second mirror plane Sxy.

The problem underlying the invention will now be described briefly with reference to 2a which is an inlet-side and outlet-side end portion of a CMD, respectively 100 in side view shows. The measuring tubes 110 flow into a collector 120 , which with a flange 122 is connected, whose end face for the connection of the CMD 100 to a pipeline. The measuring tubes 110 are in pairs by means of an inner coupler 132 and an outer coupler 134 connected. The collector 120 is over a rigid carrier body 124 with a second collector (not shown) at the other end portion of the CMD 100 connected to suppress relative movements of the collectors to each other.

As indicated by the arrows UY and UZ, however, cause the oscillations of the measuring tubes, which in the X direction, ie in the representation of 2a are excited perpendicular to the plane, a coupled movements of the collectors 120 or the associated flanges 122 , These movements can affect the performance of the meter and should therefore be minimized.

An objective function OBJ to be minimized for evaluating the success is, for example:

In this case, the absolute square of a location-dependent motion vector (UY, UZ) on the end face of the flange 122 integrated, and the integral is normalized with the face. By radicalizing this value divided by the amplitude of a sensor movement U _s in the X direction, the objective function defines an OBJ which is to be minimized. The sensor movement U _s is the movement of a vibration sensor 142a . 142b , whose position along the measuring tubes in 5c is shown.

The position p1 of the inner coupler 132 along the measuring tubes is limited as a degree of freedom for the minimization of the objective function OBJ available because the position p1 determines the free vibration length of the measuring tubes and thus the natural frequency of the measuring tube comprehensive oscillator and the sensitivity dφ / dṁ of the CMD 100 significantly influenced, wherein the angle φ a phase difference between the in 5c shown positions of the vibration sensors 142a . 142b describes the oscillator.

The position of the outer coupler 134 is therefore the remaining degree of freedom with which the objective function OBJ can be influenced. As in 2 B represented, has the function by position p2 of the second coupler 132 along the measuring tube actually an influence on the objective function, and it can be found a minimum, which is for example about OBJ (p2) 0.3025%. This value is not bad, but it can be improved.

2c now shows the influence of voice openings of a length lc in the couplers 132 . 134 to the objective function OBJ (lc), according to 2 B determined optimal position of the second coupler is maintained. The two couplers are the same design and each have the symmetry of the point group D _2h . It can be seen that the target function OBJ (lc) has a minimum at about 30 mm, which is about 0.0122% here.

The concrete dimensions of the couplers and the voice openings as well as the achievable values for the objective function OBJ are of course dependent on other parameters of the CMD, such as Measuring tube diameter, measuring tube length, arc height of the measuring tubes and number of couplers, for example by simulation using FEM to determine.

3a -D show views of embodiments of couplers 230 . 330 . 430 . 530 . 530 a CMD according to the invention. The couplers each have a flat metal plate and two tube openings 242 . 244 ; 342 . 344 ; 442 . 444 ; 542 . 544 for the measuring tubes to be coupled, which extend through the metal plate, wherein between the tube openings a vocal opening extends with a length lc. The material thickness of the metal plate is, for example, about three tube wall thicknesses of the measuring tubes to be coupled. The measuring tubes are fixed, for example by means of a braze in the tube openings.

The illustrated couplers 230 ; 330 ; 430 ; 530 ; 630 each differ in terms of further design features, which are explained below; for example, by symmetry deviations to the coupler normal plane 216 ; 316 ; 416 ; 516 ; 616 which according to the above definition runs parallel to the largest principal axis of inertia of the coupler and in which the coupler plane and a connecting line of the measuring tube axes coincide, the measuring tube axes in the coupler plane passing through the centers of the tube openings 242 . 244 ; 342 . 344 ; 442 . 444 ; 542 . 544 ; 642 . 644 run.

This in 3a shown, the first embodiment of a coupler 230 a CMD according to the invention has a symmetry of the point group D _2h . Here are therefore the centroid of the voice opening 246 and the centroid of the coupler plate in the coupler normal plane 216 ,

This in 3b shown, second embodiment of a coupler 330 a CMD according to the invention indicates in deviation 3a a vocal opening 346 whose area centroid is outside the coupler normals 316 lies.

At the in 3c shown, third embodiment of a coupler 430 of a CMD according to the invention are in deviation to 3a both the centroid of the vocal opening 446 as well as the centroid of a voice opening 346 outside the coupler normal level 416 arranged.

This in 3d shown fourth embodiment of a coupler 530 a CMD according to the invention indicates in deviation 3a a vocal opening 546 whose centroid is outside the coupler normal plane 516 lies. Furthermore, the peripheral circles of the pipe openings cut 542 . 544 in an overlap area, the vocal opening 546 so that the vocal opening 546 connected to the tube openings. The length of the overlap region perpendicular to the coupler normal plane is for example not less than 10%, in particular not less than 20% and preferably not less than 30% of the radius of the tube openings 542 . 544 , In the assembled state of the coupler in a CMD, measuring tubes run through the tube openings, which then form an edge portion of the vocal opening in the overlap region. In the overlap area, the measuring tubes remain free of a solder.

When in 3e shown, fifth embodiment of a coupler 630 a CMD according to the invention is - as in the fourth embodiment - the voice opening 646 connected to the pipe openings. Notwithstanding 3d has the voice opening here 646 in a central area a broadening, extending to the pipe openings 642 . 644 extends so that the vocal opening 546 connected to the tube openings. The length lh of widening perpendicular to the coupler normal plane is for example not less than 10%, in particular not less than 20% and preferably not less than 30% of the radius of the tube openings 642 . 644 ,

In the assembled state of the coupler in a CMD, measuring tubes run through the tube openings, which then form a marginal portion of the vocal opening. In this section, the measuring tubes remain free of a solder.

The basis of the 3a Design degrees of freedom illustrated, such as the presence or extent of deviation from the in 3a shown symmetry or the presence or the extent of an overlap region between the vocal opening and the circumferential circles of the tube openings can be combined arbitrarily. Furthermore, the tube openings may also have cross-sections deviating from the circular shape, for example elliptical.

The deviations from the symmetry in the design of a coupler and / or design differences between different couplers further allow for minimizing the stresses occurring at the couplers, which contributes to the long-term stability of the CMD's measurement properties.

The mutually facing lateral surface segments of the measuring tubes have voltage maxima in particular near the coupler normal plane in the vibrational state. A joint in this area, such as a solder joint is therefore also exposed to high voltages, which contributes to their aging. Couplers, which have open to the vocal opening tube openings, avoid this problem, since here the Lateral surface segments, which are exposed to strong stresses, can move freely.

4a . 4b and 4c show simulation results of the mechanical stress distributions in the couplers of a CMD with two inlet-side and two outlet-side couplers. However, the numerical values are not absolute as they were calculated with extremely exaggerated vibration amplitudes. In the present case, all that matters is a comparison of the relative values.

In the couplers of a CMD according to the prior art according to 4a For example, the maximum voltage at the inner coupler occurs near the coupler normal plane and is about 6.5 × 10 ¹¹ for a given amplitude of oscillation of the measuring tubes, for example.

The inventive CMD according to 4b has couplers with tune holes whose centroids are each in the coupler normal plane. Inasmuch as here the coupling forces must be absorbed by the border of the vocal opening of the coupler, it is not surprising that locally larger voltages than at the massive coupler from 4a occur. In fact, a maximum value of about 1.9 × 10 ^{12 is} almost three times the maximum value of the massive coupler. The stress peak lies on the narrow-side edge of the vocal opening on the convexly extending outside of the measuring tube arch.

According to the embodiment 4c For example, the centroids of the voids of the inner and outer couplers are shifted differently far toward the concave inner side of the measuring tube arc from the coupler normal plane, whereby the couplers on the outside of the measuring tube arc become stiffer. As a result, this leads to a reduced maximum voltage compared to the couplers with a symmetrically designed voice opening. This reduced maximum voltage occurs at the narrow side of the border of the vocal opening of the inner coupler, and at just over 1.3 × 10 ^{12 it is} only about 70% of the maximum voltage of the massive coupler of the CMD 4b ,

4d and 4e show simulation results of the mechanical stress distributions in the measuring tubes of a CMD with two inlet-side and two outlet-side couplers. As before, the numerical values are not absolute.

At the in 4d In the case of the CMD with massive couplers shown, the maximum voltage of the measuring tubes in or near the coupler normal plane of the inner coupler occurs on the side facing the respective other measuring tube and is for example about 1.29 × 10 ¹² for a given oscillation amplitude of the measuring tubes.

At the in 4e shown CMD whose coupler have voice openings occurs the maximum voltage of the measuring tubes in or near the coupler normal plane of the inner coupler on the other side of the measuring tube side and is at the same vibration amplitude only 9.46 × 10 ¹¹ is thus reduced by a good quarter. This is a significant improvement.

This in 5a . 5b and 5c illustrated embodiment of a CMD according to the invention 100 includes two parallel curved measuring tubes 110a . 110b that is between an inlet collector 120a and an outlet collector 120b extend, and are firmly connected to these, for example by rolling, brazing or welding. Between the collectors 120a . 120b extends a massive support tube 124 , which is firmly connected with both collectors, causing the collectors 120a . 120b are rigidly coupled together. The carrier tube 124 has openings at its top 125a . 125b through which the measuring tubes 110a . 110b from the collectors from the carrier tube 124 out and back again. The measuring tubes 110a . 110b are inlet side and outlet side each with two couplers 132a . 134a . 132b . 134b connected, with the coupler between the measuring tubes voice openings 146 exhibit. The couplers 132a . 132b . 134a . 134b define vibration nodes for the measuring tubes. Between the inner couplers 132a . 132b can the measuring tubes 110a . 110b swing freely, so that by the position of the inner coupler, the vibration characteristics of the through the measuring tubes 110a . 110b formed oscillator, in particular natural frequencies of vibration modes of the oscillator are significantly co-determined.

To excite vibrations with respect to the longitudinal direction or the Z-axis in the middle of the CMD 100 between the measuring tubes an exciter arrangement 140 provided, for example, an inductive excitation arrangement, which comprises, for example, a plunger coil on a measuring tube and a plunger opposite measuring tube. For detecting the vibrations of the measuring tubes are symmetrical in the longitudinal direction to the exciter arrangement 140 a first sensor arrangement 142a and a second sensor arrangement 142b provided, which are each designed as an inductive arrangement with a plunger coil on a pipe and a plunger on the other tube. Details are known to those skilled in the art, and need not be explained here. (For the sake of clarity, the positions of the exciter arrangement and the Sensor arrangements only in 5c represented, and in 5a and 5b omitted).

The collectors 120a . 120b have terminal flanges 122a . 122b by means of which the CMD is to be installed in a pipeline. Through central openings 123b in the flanges is a mass flow through the CMD 100 , in particular its pipelines 110a . 110b to conduct is to measure the mass flow.

The measuring tubes 110a . 110b are inlet side and outlet side each with two couplers 132a . 134a . 132b . 134b connected, with the coupler between the measuring tubes voice openings 146 exhibit.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102011006971 A1 [0003]
• DE 102011006919 A1 [0003]
• US 2013/0319134 A1 [0003]
• US 8281668 B2 [0003]
• US 6415668 B1 [0003]
• US 5370002 [0003]
• US 2015/0033874 A1 [0003]

Claims (19)

Coriolis mass flowmeter or density meter ( 100 ) comprising: at least two measuring tubes (curved in the rest position) ( 110a . 110b ), wherein the measuring tubes have Meßrohrachsen which mirror-symmetrically to a first mirror plane extending between the measuring tubes ( 110a . 110b ), at least one actuator arrangement ( 140 ) and at least one sensor arrangement ( 142a . 142b ); inlet side and outlet side one collector each ( 120a . 120a ), wherein the measuring tubes in each case on the inlet side and outlet side with a collector ( 3 ) are summarized in terms of flow, wherein the inlet side and outlet side provided collector ( 120a . 120b ) are designed so stable that they fulfill the functionality of a node plate; a carrier body ( 124 ), which the collector ( 120a ) and the outlet collector ( 120b ) rigidly connected with each other; and on the inlet side and outlet side in each case at least one, preferably two or more plate-shaped couplers ( 132a . 132b . 134a . 134b ) wherein the measuring tubes are connected in pairs by means of the coupler to form an oscillator, wherein the couplers each have two tube openings for the connected by the coupler measuring tubes through which the measuring tubes are guided, the measuring tubes along their circumference at least partially with the Couplers are connected, wherein the actuator assembly ( 140 ) is arranged to excite a bending vibration mode of operation between the two measuring tubes of the oscillator, the sensor arrangement ( 142a . 142b ) is adapted to detect oscillations of the oscillator, wherein on the inlet side and the outlet side in each case at least one coupler ( 132a . 132b . 134a . 134b ), between the measuring tubes connected by the coupler ( 110a . 110b ) a vocal opening surrounded by a closed edge ( 146 ) for influencing the vibration characteristics of the oscillator. Coriolis mass flowmeter or density meter ( 100 ) according to claim 1, wherein the vocal openings ( 146 ) in the first mirror plane an extension of at least 30%, for example at least 50%, and in particular at least 70% of the diameter of the measuring tubes ( 110a . 110b ) exhibit. Coriolis mass flowmeter or density meter ( 100 ) according to claim 1 or 2, wherein the voice openings in the first mirror plane have a length whose square is not less than twice, for example not less than four times and in particular not less than eight times the area of the voice opening. Coriolis mass flowmeter or density meter according to one of claims 1 to 3, wherein the distance of the Meßrohrachsen at the position of the voice openings not more than 1.5 outer diameter of the measuring tubes, in particular not more than 1.3 outer diameter and preferably not more than 1.2 Outside diameter is. Coriolis mass flowmeter or density meter nsch one of claims 1 to 4, wherein at least one coupler in the respective coupler plane has a convex hull whose area not more than five times, in particular not more than four and a half times, in particular not more than four times the outer Area of a measuring tube cross-section is. Coriolis mass flowmeter or density meter ( 100 ) according to one of the preceding claims, wherein at least two couplers of a pair of measuring tubes connected by the couplers ( 110a . 110b ) such a voice opening ( 146 ) exhibit. Coriolis mass flowmeter or density meter according to one of the preceding claims, wherein at least the two inner couplers of a pair of measuring tubes connected by the coupler have such a vocal opening on the inlet and outlet sides, wherein the two inner couplers are the couplers furthest from the respective collector. Coriolis mass flowmeter or density meter ( 1 ) according to one of claims 1 to 7, wherein the at least one voice opening is substantially symmetrical to the first mirror plane (Syz). Coriolis mass flowmeter or density meter ( 1 ) according to one of claims 1 to 8, wherein on the inlet side and the outlet side in each case at least one tuning opening of a coupler with respect to a coupler normal plane ( 16 ), is asymmetrical, the coupler normal plane extending parallel to the largest main axis of inertia of the coupler, perpendicular to the first mirror plane, and a perpendicular to the first mirror plane extending connecting line of the Meßrohrachsen ( 12a . 12b ) within the vocal opening. Coriolis mass flowmeter or density meter ( 1 ) according to claim 9, wherein the distance of the outermost extent of the at least one voice opening in the first mirror plane (Syz) from the coupler normal plane ( 16 ) on a first Side of the coupler normal plane is less than on a second side of the coupler normal plane. Coriolis mass flowmeter or density meter ( 1 ) according to any one of the preceding claims, wherein the distance between the outermost extension of the vocal aperture in the first mirror plane and an outermost extent of the coupler in the first mirror plane is lower on a first side of the coupler normal plane than on a second side of the coupler normal plane, the coupler normal plane being parallel extends to the largest main axis of inertia of the coupler, is perpendicular to the first mirror plane, and extending perpendicular to the first mirror plane connecting line of the Meßrohrachsen ( 12a . 12b ) within the vocal opening. Coriolis mass flowmeter or density meter ( 1 ) according to one of the preceding claims, wherein at least one coupler on the inlet side and on the outlet side has a center of gravity which is a distance away from a coupler normal plane, the distance being for example not less than 4%, in particular not less than 8% of the distance of the measuring tube axes the coupler normal plane is, wherein the coupler normal plane extends parallel to the largest main axis of inertia of the coupler, perpendicular to the first mirror plane, and extending perpendicular to the first mirror plane connecting line of the Meßrohrachsen ( 12a . 12b ) within the vocal opening. Coriolis mass flowmeter or density meter ( 1 ) according to one of the preceding claims, wherein at least one coupler on the inlet side and on the outlet side has a centroid of a minimum convex envelope which is a distance away from a coupler normal plane, the distance being for example not less than 4%, in particular not less than 8% The distance of the measuring tube axes in the coupler normal plane is, with the coupler normal plane extending parallel to the largest main axis of inertia of the coupler, perpendicular to the first mirror plane, and extending perpendicular to the first mirror plane connecting line of the Meßrohrachsen ( 12a . 12b ) within the vocal opening. Coriolis mass flowmeter or density meter ( 1 ) according to one of the preceding claims, wherein inlet side and outlet side each have a first coupler and a second coupler coupler specific Kopplernormalenebenen each extending parallel to the largest main axis of inertia of the respective coupler, which extend perpendicular to the first mirror plane, and extending perpendicular to the first mirror plane connecting line the measuring tube axes ( 12a . 12b ) within the voice port of the respective coupler, the first coupler having a first center of mass spaced from its coupler-specific coupler normal plane by a first distance, the second coupler having a first center of mass spaced from its coupler-specific coupler normal plane by a second distance wherein the first distance deviates from the second distance, the deviation being for example not less than 5%, in particular not less than 10% of the smaller of the two distances. Coriolis mass flowmeter or density meter ( 1 ) according to one of the preceding claims, wherein inlet side and outlet side each have a first coupler and a second coupler coupler specific Kopplernormalenebenen each extending parallel to the largest main axis of inertia of the respective coupler, which extend perpendicular to the first mirror plane, and extending perpendicular to the first mirror plane connecting line the measuring tube axes ( 12a . 12b ) within the vocal aperture of the respective coupler, each inlet side and outlet side having a first centroid of a minimum convex envelope and a second coupler having a second centroid of a minimum convex envelope, the first centroid of its coupler specific coupler normal plane about a first convex envelope Spacing is spaced, wherein second centroid is spaced from its coupler specific coupler normal plane by a second distance, the first distance being different from the second distance, the deviation being for example not less than 5%, in particular not less than 10% of the smaller of the two Distances is. Coriolis mass flowmeter or density meter ( 1 ) according to one of the preceding claims, wherein inlet side and outlet side each have a first coupler and a second coupler coupler specific Kopplernormalenebenen each extending parallel to the largest main axis of inertia of the respective coupler, which extend perpendicular to the first mirror plane, and extending perpendicular to the first mirror plane connecting line the measuring tube axes ( 12a . 12b within the vocal aperture of the respective coupler, the first coupler having a first vocal aperture, the second coupler having a second vocal aperture, and wherein the first vocal aperture differs from the second vocal aperture in at least one parameter of the following parameters: Length of the vocal opening, distance of the Centroid of the vocal aperture to the respective coupler normal plane. Coriolis mass flowmeter or density meter ( 1 ) according to one of the preceding claims, wherein each inlet side and outlet side at least one voice opening is bounded by edge portions which are formed in a section between the measuring tubes on both sides by the measuring tubes. Coriolis mass flowmeter or density meter ( 1 ) according to claim 17, wherein the edge sections formed by the measuring tubes perpendicular to the largest principal axis of inertia of the respective coupler each have a length which is not less than 10%, in particular not less than 20% and preferably not less than 30% of the radius of the measuring tube, which forms the respective edge portion of the vocal opening. Coriolis mass flowmeter or density meter ( 1 ) according to one of the preceding claims, wherein the plate-shaped bodies have a material thickness which is not more than four times, in particular not more than three times, the wall thickness of the measuring tubes.

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