MEASURING DEVICE

Abstract

A measuring device includes a measuring transducer, which includes a protection housing, two connection connectors, and a fluid line, which extends from a first end to a second end, wherein the first and second ends of the fluid line are each connected to one of the connection connectors, respectively, and wherein at least one of the connection connectors includes a metal compensator in a region located between a first connector end and a second connector end, which second end forms an end of the protection housing adjacent the first and/or second end of the fluid line.

Claims

1. A measuring device for measuring at least one measurement variable of a fluid measured substance that is, in particular, conducted in a pipe, which measuring device comprises: a measuring transducer, in particular vibronic or magnetic-inductive or acoustic, measuring transducer, which can be used to generate at least one measurement signal that corresponds to the at least one measurement variable; and a measuring device electronic unit, which is electrically connected to the measuring transducer and can be used to process the at least one measurement signal; wherein the measuring transducer comprises a (transducer) protection housing, a first connection connector, in particular designed as a line branch and/or rotationally symmetrical with respect to an (imaginary) longitudinal axis, having a lumen that is encased by a wall made of metal and extends from a first flow opening located in a first connector end of the first connection connector, and in particular framed by a connection flange, to a second flow opening located in a second connector end of said first connection connector, in particular rotationally symmetrical with respect to an (imaginary) longitudinal axis of the first connection connector, a second connection connector, in particular structurally identical to the first connection connector and/or serving as a line combining and/or being rotationally symmetrical with respect to a (imaginary) longitudinal axis, encased by a wall, in particular of a metal, extending from a first flow opening located in a first connector end of the second connection connector (400), in particular a connection flange, to a second flow opening located in a second connector end of said second connection connector, in particular with respect to a (imaginary) longitudinal axis of the second connection connector rotationally symmetrical, and a first fluid line, in particular formed as a rigid and/or at least partially circular cylindrical tube, comprising a lumen that is encased by a wall, in particular made of metal, and extends from a first flow opening located in a first line end of the first fluid line to a second flow opening located in a second line end of said first fluid line; wherein the first fluid line is connected both at its first line end to the second line end of the first connection connector and at the second line end thereof to the second line end of the second connection connector, in particular in a bonded manner in each case, in particular in such a way that the lumen of the first fluid line communicates with both the lumen of the first connection connector and the lumen of the second connection connector while forming a fluid duct extending from the first connection connector to the second connection connector and/or in such a way that the first flow opening of the first fluid line opens into the second flow opening of the first connection connector and the second flow opening of the first fluid line opens into the second flow opening of the second connection connector; wherein said (transducer) protection housing comprises a cavity encased by a wall, in particular made of a metal, within which the first fluid line is placed; wherein a first housing end of the protection housing is formed by means of the first connection connector and a second housing end of the (transducer) protection housing is formed by means of the second connection connector such that the protection housing has a side wall laterally bounding the cavity, at least in part, which is connected in a fixed manner both at the second line end of the first connection connector and also at the second line end of the second connection connector or is connected in a bonded manner therewith in each case; wherein at least the first connection connector has, in a region located between its first connector end and its second connector end, which forms the first housing end, in particular specifically remote from its first connector end and/or from the first housing end, a metal compensator that is in particular integrated and/or formed as an axial compensator, in particular such that the metal compensator is an integral component of the first connection connector and/or that the first connection connector reacts to a (tensile) force in the region of the metal compensator with a (longitudinal) extension which is greater than a (longitudinal) extension with which the first connection connector reacts in the region of the first connector end and/or in the region of the second connector end to said (tensile) force, and/or that the first connection connector reacts to a (tensile) force in the region of the metal compensator acting transversally to the longitudinal axis that brings about an, in particular straight (transverse force) bending of the first connection connector with a curvature that is greater than a curvature with which the first connection connector reacts to said (transverse) force in the region of the first connector end and/or in the region of the second connector end.

2. The measuring device according to claim 1, wherein the first connection connector is configured to react to a (tensile) force acting in the direction of a longitudinal axis of the first connection connector in the region of the metal compensator with a (longitudinal) extension which is greater than a (longitudinal) extension with which the connection connector reacts to said (tensile) force in the region of the first connector end and/or in the region of the second connector end; and/or wherein the first connection connector is configured to react to a (transverse) force in the region of the metal compensator acting transverse to the longitudinal axis that brings about a (transverse force) bending, that is in particular straight, of the first connection connector with a curvature that is greater than a curvature with which the first connection connector reacts to said (transverse) force in the region of the first connector end and/or in the region of the second connector end.

3. The measuring device according to either of the claim 1, wherein the metal compensator has at least one recess running in particular along a circular and/or self-enclosed circumferential line, in particular formed as a bead and/or self-enclosed.

4. The measuring device according to claim 1, wherein the metal compensator is formed by at least one recess running along a circular and/or self-enclosed circumferential line, in particular formed as a bead and/or self-enclosed, in the wall of the first connection connector.

5. The measuring device according to claim 1, wherein the metal compensator has an integral component of the first connection connector, in particular by the wall of the first connection connector having at least one recess running in particular along a circular and/or self-enclosed circumferential line, in particular formed as a bead and/or self-enclosed.

6. The measuring device according to claim 1, wherein the wall of the first connection connector for forming the metal compensator has at least one recess, formed in particular as a bead and/or self-enclosed, running in particular along a circular and/or self-enclosed circumferential line and/or is formed in sections as a metal bellows, in particular by the wall of the first connection connector being corrugated at least in sections and/or by the first connection connector having an internal diameter varying in a corrugated manner in the direction of the longitudinal axis and an outer diameter varying in an equivalent corrugated manner.

7. The measuring device according to claim 6, wherein the wall of the first connection connector has two or more recesses, in particular of the same shape, which are arranged one behind the other in the flow direction.

8. The measuring device according to claim 1, wherein the metal compensator of the first connection connector is designed as a corrugated tube compensator.

9. The measuring device according to claim 1, wherein the metal compensator of the first connection connector is designed as a lens compensator.

10. The measuring device according to claim 1, wherein the metal compensator of the first connection connector is designed as an axial compensator.

11. The measuring device according to claim 1, wherein the second connection connector hasin a region located between its first connector ends and its second connector ends forming the first housing end, in particular specifically remote from its first connector end and/or the first housing enda metal compensator, in particular integrated and/or formed as an axial compensator, in particular such that the metal compensator is an integral component of the first connection connector and/or is structurally identical to the metal compensator of the first connection connector.

12. The measuring device according to claim 1, wherein the second connection connector does not have a metal compensator.

13. The measuring device according to claim 1, wherein the measuring transducer is configured to be integrated in a piping system, in particular in such a way that the second connector end of the first connection connector is connected to a pipe end of a first pipe segment of the piping system facing the measuring transducer and/or that the second connector end of the second connection connector is fluidically connected to a pipe end of a second pipe segment of the piping system facing the measuring transducer, in particular to form a fluid duct that extends from the first pipe segment to the second pipe segment and/or is leakage-free.

14. The measuring device according to claim 1, wherein the first and second connection connectors are aligned with one another, in particular in such a way that an extension of a longitudinal axis of the first connection connector is parallel to or coincides with an extension of a longitudinal axis of the second connection connector.

15. The measuring device according to claim 1, wherein the first fluid line is configured such that the measured substance flows through it and it is allowed to vibrate during the process.

16. The measuring device according to claim 1, wherein the measuring device electronics are configured to feed an electrical driver signal into the measuring transducer.

17. The measuring device according to claim 1, wherein the first fluid line, at least in sections, is curved, in particular V-shaped and/or U-shaped and/or circular arc-shaped; and/or wherein the first fluid line is straight, at least in sections, in particular in the specific form of a hollow cylinder.

18. The measuring device according to claim 1, further comprising: at least one second fluid line, which is formed in particular as a rigid and/or at least partially circular cylindrical tube and/or structurally identical to the first fluid line, having a lumen extending from a first flow opening encased by a wall made, in particular, out of metal, which is located in a first line end of the second fluid line, to a second flow opening located in a second line end of said second fluid line, wherein the second fluid line is connected at its first line end to the second line end of the first connection connector and at its second line end to the second line end of the second connection connector, in particular in such a way that both the lumen of the first fluid line and the lumen of the second fluid line communicate both with the lumen of the first connection connector and with the lumen of the second connection connector and/or in such a way that the first flow opening of the second fluid line opens into a third flow opening of the first connection connector, which is also located in the second connector end of the first connection connector, and the second flow opening of the second fluid line opens into a third flow opening of the second connection connector, which is also located in the second connector end of the second connection connector.

19. The measuring device according to claim 18, wherein the second fluid line is configured such that the measured substance flows through it in particular simultaneously with the first fluid line and during this is allowed to vibrate in particular simultaneously with the first fluid line.

20. The measuring device according to claim 1, further comprising: at least one, in particular electromechanical or electrodynamic, vibration exciter for exciting or maintaining mechanical vibrations, in particular bending vibrations, at least of the first fluid line, in particular for exciting or maintaining mechanical vibrations both of the first fluid line and of the second fluid line.

21. The measuring device according to claim 20, wherein the measuring device electronics are electrically coupled to the vibration exciter, in particular in order to feed electrical power into the vibration exciter by means of an electrical driver signal; and/or wherein the vibration exciter is configured to convert electrical power fed by the measuring device electronics, in particular by means of an electrical driver signal, into mechanical power causing mechanical vibrations of at least the first fluid line, in particular of both the first fluid line and a second fluid line.

22. The measuring device according to claim 1, further comprising: at least one first sensor in particular mounted on the first fluid line and/or placed in the vicinity thereof for generating at least onein particular electricalfirst measurement signal corresponding to a measurement variable of a fluid conducted in the fluid line system of said at least one signal parameter dependent on said measurement variable, in particular a signal level dependent in particular on said measurement variable and/or a signal frequency dependent on said measurement variable and/or a phase angle dependent on said measurement variable.

23. The measuring device according to claim 22, wherein the measuring device electronics are electrically coupled to the first sensor and are configured to process the at least first measurement signal, in particular to determine said measured values for the at least one measurement variable by means of the first measurement signal.

24. The measuring device according to claim 23, further comprising: at least one second sensor, in particular mounted at least on the first fluid line and/or at least placed in the vicinity thereof and/or a second sensor structurally identical to the first sensor, for generating at least onein particular electricalsecond measurement signal corresponding to the measurement variable, wherein the measuring device electronics are electrically coupled to the second sensor and are configured to process the at least second measurement signal, in particular to determine said measured values for the at least one measurement variable by means of the first and second measurement signals.

25. Use of a measuring device according to claim 1 for determining measured values for at least one measurement variablein particular specifically a mass flow rate, a mass flow, a volumetric flow rate, a volumetric flow rate, a density, a viscosity or a temperatureof a fluid measured substance conducted in a pipe, in particular a gas, a liquid or a dispersion, in particular such that the first connection connector is arranged on the inlet side with respect to a flow direction of the measured substance which flows through the measuring transducer and/or that the measured substance is allowed to flow in a predetermined flow direction through the pipe and the measuring transducer incorporated in said pipe.

Description

[0046] In the figures in detail:

[0047] FIG. 1 schematically shows an exemplary embodiment of a measuring device according to the invention; and

[0048] FIG. 2 schematically shows a further variant for a measuring device according to the invention.

[0049] In FIGS. 1 and 2, a measuring device or different design variants of such a measuring device, in some cases also complementary to one another, are shown schematically, which design variants are provided in particular for determining measured values for at least one measurement variablefor example specifically a mass flow rate, a mass flow, a volumetric flow rate, a volumetric flow, a density, a viscosity or a temperatureof a fluid measured substance conducted in a pipe, for example, specifically a gas, a liquid or a dispersion. The measuring device comprises a measuring transducer 10in particular a vibronic or magnetic-inductive or acoustic onewhich can be used to generate at least one measurement signal s1 (s1, s2) that corresponds to the at least one measurement variable, and in particular has the said at least one signal parameter which is dependent on the measured value and/or is electrical, and a measuring device electronic unit 20 which is electrically connected to the measuring transducer and can be used to process the at least one measurement signal s1 (s1, s2). As is quite usual in the case of measuring devices of the type in question, the measuring device electronics 20 can also be accommodated in an electronics protection housing 2000 that is, for example, metallic and/or explosion-resistant and/or seals against spray water and/or dust.

[0050] The measuring transducer 10 comprises at least one fluid line 200formed for example as a rigid and/or at least in some parts circular cylindrical tubea first connection connector 100for example, rotationally symmetrical with respect to an (imaginary) longitudinal axisand a second connection connectortypically rotationally symmetrical with respect to the first connection connector 400 and/or with respect to an (imaginary) longitudinal axis.

[0051] The fluid line 200 of the measuring transducer 10 has a lumen encased by a wall, for example made of metal, such as a stainless (noble) steel, a titanium alloy, a tantalum alloy, a zirconium alloy, etc. and extending from a first flow opening located in a first line end of the fluid line 200 to a second flow opening located in a second line end of said fluid line and each of the two connection connectors 100, 400 has in each case a respective first flow opening encased by a wall, in particular made of metal, for example a rustproof (stainless) steel, and extending from a first flow opening-typically framed by a (standardized) connecting flange (101, 401)located in a respective first connector end 100+ or 400+ of the respective connection connector 100, 400 to a second flow opening located in a second connector end 100 # or 400 # of said connection connector 100, 400, for example a lumen which is rotationally symmetric with respect to an (imaginary) longitudinal axis of the respective connection connector 100 or 400. Moreover, the fluid line 200 is connected both at its first line end 200+ to the second line end 100 # of the first connection connector 100 and at the second line end 200 # thereof to the second line end 400 # of the second connection connector 400, in particular in such a way that the lumen of the fluid line 200 communicates with both the lumen of the first connection connector 100 and the lumen of the second connection connector 200 while forming a fluid duct extending consistently from the connection connector 100 to the connection connector 400, or that the flow opening of the fluid line 100 opens into the second flow opening of the connection connector 200 and the second flow opening of the fluid line 200 opens into the second flow opening of the second connection connector 400.

[0052] The fluid line 200 can, for example, be connected in a bonded manner to each of the two connection connectors. Furthermore, the fluid line 200 can also be designed at least partially straight, for example, specifically hollow-cylindrical, and/or at least in some sections curved, for example specifically in a V-shape and/or U-shape and/or a circular arc shape. Furthermore, the measuring transducer, as also indicated in FIG. 2, may comprise at least one second fluid line 300, which is, for example, structurally identical to the fluid line 200, wherein, in this case, the at least two fluid lines 200, 300 can in addition each be connected at the respective first line ends 200+, 300+ thereof to the second line end 100 # of the connection connector 100then formed, for example, as a line branchand at its respective second line ends 200 #, 300 # in each case to the second line end 400 # of the connection connector 400then formed, for example, as a line mergerthis being done in particular in such a way that both the fluid line 200 at its first line end 200+ and the fluid line 300 at its first line end 300+ are each connected to the second line end 100 # of the connection connector 100 and both the fluid line 200 at its second line end 200 # and the fluid line 300 at its second line end 300 # are each connected to the second line end 400 # of the connection connector 400, or in such a way that both the lumen of the fluid line 200 and the lumen of the fluid line 300 communicate with the lumen of the connection connector 100 and/or in such a way that the first flow opening of the fluid line 200 opens into the second flow opening of the connection connector 100 and the first flow opening of the fluid line 300 opens into the second flow opening of the connection connector 100, likewise located in the line end 100 #, and the second flow opening of the fluid line 200 opens into the second flow opening of the connection connector 400 and the second flow opening of the fluid line 300 opens into a third flow opening of the connection connector 400, likewise located in the line end 400 #. Furthermore, the measuring transducer, if necessary, can have further fluid lines connected to the connection connectors and accommodated inside the protection housing 1000, for example, specifically as shown in the aforementioned US-A 2010/0236338 or US-A 2017/0261474, respectively, four parallel and at least pairwise identical fluid lines or, as proposed in US-A 2012/0279317, mentioned at the outset, eight or more fluid lines.

[0053] In order to generate the at least one measurement signal s1, the measuring device according to a further embodiment of the invention comprises at least one first sensor 1000, which is for example mounted at least in part on the at least one fluid line 100 and/or placed at least in its vicinity. In order to process the measurement signal s1, for example, specifically to determine measured values for the at least one measurement variable on the basis of the measurement signal s1, the measuring device electronics can also be electrically coupled to the sensor 51.

[0054] According to a further embodiment of the invention, the measuring transducer is designed as a vibration-type measuring transducer in such a way that the measured substance is configured to flow through at least one of its fluid lines, in particular each of its fluid lines, to have it vibrate during this; for the above-described case that two or more fluid lines are provided, for example also simultaneously. For exciting or maintaining mechanical vibrations, for example said bending vibrations, at least of the fluid line 200, in some cases also for exciting or maintaining mechanical vibrations both of the fluid line 200 and of the fluid line 300, the measuring transducer or the measuring device formed therewith further comprises at least one (electromechanical), for example, said electrodynamic or electromagnetic vibration exciter 41. The vibration exciter 41 is electrically connected to the measuring device electronics and, in particular, is additionally configured to convert electrical power fed from the measuring device electronics, for example, specifically by means of a corresponding electrical driver signal el of the measuring device electronics, into mechanical power which creating mechanical vibrations of at least the fluid line 200, this being provided for the above-described case that two fluid lines (200, 300) are provided, for example also in such a way that the two fluid lines (200, 300) carry out opposing (flexural) vibrations. In particular for the above-described case in which the measuring transducer 10 is designed as a measuring transducer of the vibration type, the sensor 51 can also be designed as, for example, an electrodynamic or optoelectrical vibration sensor. Alternatively or in addition, the measuring transducer 10 may also be equipped with at least one second (vibration) sensor 52, which is, for example, attached to and/or placed at least close to the fluid line 200 and/or is structurally identical to the aforementioned sensor 51, for generating at least one second, in particular electrical, measurement signal s2, which also corresponds to the at least one measurement variable. In addition, the measuring device electronics 20 can also be electrically coupled to the sensor 52, for example similarly to the sensor 51, and can also be configured to process the measurement signal s2 thereof, in particular to determine, by means of the first and second measurement signal s1, s2, measured values for the at least one measurement variable, for example specifically to calculate measured values for the mass flow rate or the mass flow on the basis of a phase difference established between the measurement signals.

[0055] The measuring transducer 10 of the measuring device according to the invention further comprises a (transducer) protection housing 1000 with a cavity encased by a wall, for example made of a metal, in particular a rustproof (stainless) steel, within which the at least one fluid line 200 or each of the fluid lines of the measuring transducer is placed. In addition, a first housing end 1000+ of the protection housing 1000 is formed by means of the connection connector 100 and a second housing end 1000 # of the protection housing 1000 by means of the connection connector 400, such that the protection housing 1000 has a side wall laterally bounding its pre-designated cavity, at least in part, said side wall laterally being connected in a fixed and bonded manner both at the second line end 100 # of the connection connector 100 and also at the second line end 400 # of the connection connector 400. The transducer protection housing 1000 can also, for example, be mechanically fixedly connected to the pre-designated electronics protection housing for the measuring system electronics to form a measuring device of compact construction, in such a way that the electronics protection housing 2000 is held directly and/or only by the transducer protection housing.

[0056] As already mentioned, the measuring transducer is in particular provided or configured to be integrated into a (pipe) system comprising the aforementioned pipe, for example specifically in such a way that the connector end 100+ of the connection connector 100 is fluidically connected at a pipe end of a first pipe segment of the piping system that faces the measuring transducer 10 and/or that the connector end 400+ of the connection connector 400 is fluidically connected, to a pipe end of a second pipe segment of the piping system that faces the measuring transducer, in particular also in a leakage-free manner, for example specifically to form a fluid duct extending continuously from the aforementioned first pipe segment to the aforementioned second pipe segment and/or in such a way that the measured substance (during operation) is allowed to flow in a predetermined flow direction through the pipe and the measuring transducer incorporated therein. According to a further embodiment of the invention, the connection connectors 100, 400 are accordingly arranged and aligned in such a way that they are aligned with one another, for example specifically in such a way that an extension of a longitudinal axis of the connection connector 100 is parallel to an extension of a longitudinal axis of the connection connector 400 or coincides therewith.

[0057] In order to be able to compensate for a possible offset between the aforementioned pipe segments which are each connected to the measuring transducerfor example in such a way that the longitudinal axes of the two pipe segments in extension are displaced parallel to one another or also skewed and/or in such a way as to be able to compensate within the measuring transducer for a distance between the pipe segments greater than a distance between the connector ends 100+, 400+ corresponding to an installation length of the measuring transduceror in order to prevent such an offset of the pipe segments from causing such forces and/or torques or mechanical stresses within the measuring transducer that can deform the at least one fluid line 200 to an impermissibly high degree, adversely affecting specifically the measurement accuracy of the measuring device, in the measuring transducer according to the invention, at least the connection connector 100 has in a region located between its connector end 100+ and its connector end 100#forming the first housing end 1000+, thus outside the protection housing 1000, a metal compensator 110. The metal compensator 110 serves in particular to configure the connection connector 100 to react to a (tensile) force acting in the direction of the longitudinal axis thereof in the region of the metal compensator 110 defined with a (longitudinal) expansion which is greater than a (longitudinal) expansion with which the connection connector 100 reacts in the region of the connector end 100+ and/or in the region of the connector end 100 # to said (tensile) force in each case. Alternatively or in addition, the metal compensator 110 can also be used to configure the connection connector 100 to react to a (transverse) force, which acts transversely to the longitudinal axis thereof, to cause a bending of the connection connector 100for example taking the form of a straight bending and/or a transverse force bendingor a bending moment at the connector end 100+ in the region of the metal compensator with a curvature which is greater than a curvature with which the connection connector 100 reacts in the region of its connector end 100+ and/or in the region of its connector end 100 # to said (transverse) force or said bending moment. The aforementioned region of the connection connector 100 or the metal compensator 110 provided therein can accordingly be directly adjacent to the housing end 1000+, for example, or, as also shown schematically in FIG. 1, can be at a distance not only from the connector end 100+ but also from the housing end 1000+. Depending on the application or depending on the type of offset to be compensated, the metal compensator 110 can be designed, for example, as a corrugated tube compensator, as a lens compensator or, for example, also as an axial compensator.

[0058] According to a further embodiment of the invention, the metal compensator 110 has at least one recess, for example running along a circular and/or self-enclosed circumferential line, which recess can be formed, for example, as a bead recessed towards the lumen of the connection connector or, as also indicated in FIG. 1, as a bead which protrudes with respect to the lumen of the connection connector. In addition, the metal compensator can be designed as an integral component of the connection connector 100, for example in such a way that the aforementioned at least one recess is formed directly within the wall of the connection connector 100, for example, specifically rolled or stamped therein.

[0059] Alternatively or in addition, the metal compensator 110 can be designed in sections as a metal bellows, specifically as a ring-shaped cylinder made of metal with an inner diameter varying in a corrugated manner in the direction of the longitudinal axis and an outer diameter equivalently varying in a corrugated manner, for example in such a way that the wall of the connection connector 110 has two or more, in particular identically shaped, recesses arranged one behind the other in the flow direction and/or in that the wall of the connection connector 100 is corrugated at least in sections or in that the connection connector 100 has an internal diameter varying in a corrugated manner in the direction of the longitudinal axis and an outer diameter equivalently varying in a corrugated manner.

[0060] In order to further improve the compensation of the above-described offset between the pipe segments to be connected to the measuring transducer which can already be achieved by means of the metal compensator 110, it is also possible, as shown schematically in FIG. 2, for the connection connector 400 to have a metal compensator 410, for example also structurally identical to the metal compensator 110, located in a region between its first connector end 400+ and its second connector end 400 #, which forms the second housing end 1000 #. Alternatively, however, it is possible that the second connection connector also does not have a metal compensator, for example in order to keep a pressure loss, which is provoked by the measuring transducer as a whole in the flowing measured substance, as low as possible. In this case, it can also be advantageous to incorporate or use the measuring device in the pipe in such a way that the connection connector 100 is arranged on the inlet side with respect to a flow direction of the measured substance allowed to flow through the measuring transducer.