DE102006047815A1 - Measuring system e.g. magnetic-inductive flow measuring system, for detecting measurement variable e.g. mass flow of medium, has flow conditioner with inner edge that is provided upstream of outlet end of conditioner and projects into lumen - Google Patents

Abstract

The measuring system is used in the course of a process line and serves to detect at least one measured variable of a medium flowing in the process line. It comprises for this purpose a measuring transducer with a measuring tube serving to guide the measuring tube and with a sensor arrangement which has at least one sensor element reacting primarily to the measured variable to be detected and which supplies at least one measuring signal influenced by the measuring variable by means of the at least one sensor element. Furthermore, the measuring system comprises a measuring electronics communicating with the measuring transducer, which at least temporarily generates at least one measured value currently representing the measured variable using the at least one measuring signal. In the measuring system according to the invention, the measuring tube has a smaller flow cross-section than an inlet segment of the process line connected to the measuring system on the inlet side. Therefore, the measuring system further comprises an inlet side of the measuring tube, arranged between this and the inlet segment of the process line mediating flow conditioner, which has a tapered towards the measuring tube, in operation by the medium flowed through lumen. The flow conditioner has at least one impingement surface arranged upstream of its outlet end and projecting into the lumen of the flow conditioner, which has flowed during the operation of medium conducted therein.

Description

The The invention relates to a measuring system for measuring at least one measured variable, esp. a mass flow, a density, a viscosity, a Pressure or the like, a medium flowing in a process line with a transducer and a flow conditioner mediating between it and the process line.

In the industrial process measuring technique Especially in connection with the automation of chemical or process engineering, for the detection of process-descriptive Measured variables and to produce these representing measured-value to the process installed measuring systems used, each directly on or in a process flow through the medium are attached. In each case to be detected measured variables For example, it is a mass flow, a volume flow, a Flow velocity, a density, a viscosity or a temperature or the like, of a liquid, powder, steam or gaseous Process medium act in such a way, for example designed as a pipeline, process line guided or held.

Among the measuring systems are, inter alia, those in which in-line measuring devices with magnetic-inductive transducers or the duration of ultrasound waves emitted in the flow direction, esp. Also working on the Doppler principle, transducers, with transducers of the vibration type, esp Coriolis mass flow sensors, density sensors, or the like can be used. The basic structure and operation of magnetic-inductive transducer is eg in the EP-A 1 039 269 . US-A 60 31 740 . US-A 55 40 103 . US-A 53 51 554 . US-A 45 63 904 or such ultrasonic transducer, for example in the US-B 63 97 683 , of the US-B 63 30 831 , of the US-B 62 93 156 , of the US-B 61 89 389 , of the US-A 55 31 124 , of the US-A 54 63 905 , of the US-A 51 31 279 , of the US-A 47 87 252 described sufficiently and also the skilled person also sufficiently known, can be dispensed with a more detailed explanation of these principles of measurement at this point. Further examples of such, known to those skilled in and of themselves, in particular by means of compact in-line measuring instruments, measuring systems are also in the EP-A 984 248 . GB-A 21 42 725 . US-A 43 08 754 . US-A 44 20 983 . US Pat. No. 4,468,971 . US-A 45 24 610 . US-A 47 16 770 . US Pat. No. 4,768,384 . US-A 50 52 229 . US-A 50 52 230 . US-A 51 31 279 . US-A 52 31 884 . US-A 53 59 881 . US-A 54 58 005 . US-A 54 69 748 . US-A 56 87 100 . US Pat. No. 5,796,011 . US-A 58 08 209 . US-A 60 03 384 . US-A 60 53 054 . US-A 60 06 609 . US-B 63 52 000 . US-B 63 97 683 . US-B 65 13 393 . US-B 66 44 132 . US-B 66 51 513 . US-B 68 80 410 . US-B 69 10 387 . US-A 2005/0092101 . WO-A 88/02 476 . WO-A 88/02 853 . WO-A 95/16897 . WO-A 00/36 379 . WO-A 00/14485 . WO-A 01/02816 or WO-A 02/086 426 described in detail.

To the Detecting the respective measured variables point Measuring Systems the type in question in each case a corresponding transducer on, in the course of a medium-leading process management is used and serves to at least one of the primarily detected measured variable as possible exactly representative, esp. electrical, measuring signal to create. Therefore the transducer is usually with one in the course of the respective process line, the leading of pouring Medium serving measuring tube and a corresponding physical-electrical sensor arrangement fitted. This in turn has at least one primary on the to be detected measurand or also changes the same reacting sensor element, by means of the in operation at least one of the measured quantity accordingly influenced measuring signal is produced. For further processing or evaluation of at least a measuring signal is the transducer further with a corresponding thereto suitable measuring electronics connected. The with the transducer appropriately communicating measuring electronics generated in operation of the measuring system using the at least one measurement signal at least temporarily at least one the measured variable currently representing measured value, for example, a mass flow rate, volumetric flow rate, a Density reading, a viscosity reading, a Pressure measured value, a temperature reading or similar.

For receiving the measuring electronics such measuring systems further comprise a corresponding electronics housing, such as in the US-A 63 97 683 or the WO-A 00/36 379 suggested, arranged away from the transducer and can be connected to this only via a flexible line: Alewtrantiv to the electronics housing but also, as in the EP-A 903,651 or the EP-A 1 008 836 to form a compact in-one meter - for example, a Coriolis mass flow / density meter, an ultrasonic flowmeter, a vortex flowmeter, a thermal flowmeter, a magnetic flowmeter or the like - directly on the transducer or a the measuring transducer separately housed Meßaufnehmer housing may be arranged. In the latter case, the electronics housing, such as in the EP-A 984 248 , of the US-A 47 16 770 or the US-A 63 52 000 shown, often also to include some mechanical components of the transducer with, such as under mechanical action operatively deforming membrane, rod, sleeve sen- or tubular deformation or vibration body, cf. this also the aforementioned US-B 63 52 000 ,

Measuring Systems of the type described above also usually via a connected to the measuring electronics Data transmission system with each other and / or associated with appropriate process hosts, where they are the measured value signals e.g. via (4 mA to 20 mA) current loop and / or via digital data bus send. As data transmission systems are used here, esp. Serial, field bus systems, such. PROFIBUS PA, FOUNDATION FIELDBUS and the corresponding transmission protocols. By means of the process control computer can the transferred ones measured value signals further processed and as corresponding measurement results e.g. on monitors visualized and / or in control signals for process actuators, e.g. Solenoid valves, Electric motors, etc., to be converted.

Like in the GB-A 21 42 725 . US-A 58 08 209 . US-A 2005/0092101 . US-B 68 80 410 . US-B 66 44 132 . US-A 60 53 054 . US-B 66 44 132 . US-A 50 52 229 or the US-B 65 13 393 discussed, in-line measuring devices and extent also measuring system of the type described may well have a more or less dependent on the type of flow measurement accuracy. Of particular interest in this connection is also an instantaneous expression of an effective flow profile in the measuring tube. In view of the fact that turbulent flows, ie flows with a Reynolds number greater than 2300, are largely similar to each other over a wide range of Reynolds numbers and, to that extent, also have a comparable influence on the measurement accuracy, in many measurement systems, a high flow rate is often required for the medium to be measured sought. Vortex flowmeters are usually dependent on such currents to achieve a sufficiently high accuracy, which have a Reynolds number of well over 4000.

Therefore it is with measuring systems the type in question quite common, at least in process lines with a comparatively large one Caliber and / or in applications with comparatively slow flowing media, the measuring tube optionally in such a way that it has a smaller flow cross section has, as an inlet side to the measuring system Connected inlet segment of the process line. As a result, learns that flowing Medium then an acceleration in the flow direction, which in turn also an increase the Reynolds number can be achieved. The realization of this principle has proven itself in particular in such measuring systems, the by means of an ultrasonic measuring device and / or work by means of a vortex flowmeter and / or for the measurement of at least a proportion of, in particular predominantly or completely, gaseous media are provided.

in the Consider also that, for example the measuring principle context of vortex flowmeters between a stripping rate of vertebrae on one of the currents opposing bluff body and the primary with it to be detected measured volume volume flow or flow velocity only above a Reynolds number of 20,000 sufficiently as linear may be considered, may be a comparatively large difference between the flow cross sections from the process line and measuring tube to realize. In other words, for this Reynolds number range the representative of the aforementioned context Strouhalzahl be assumed to be largely constant.

In order to create as short a distance as possible a defined transition region from the inlet segment to the measuring tube with a smaller flow cross-section, it is, inter alia, in the GB-A 21 42 725 , of the US-A 58 08 209 or US-A 2005/0092101 proposed, customary in the measuring system to provide a corresponding flow conditioner with a tapered towards the measuring tube, in the operation of the medium flowed lumen, which is arranged on the inlet side of the measuring tube and thus acts mediating between this and the inlet segment of the process line. An inlet end of the flow conditioner facing the inlet segment of the process line has a flow cross section which is greater than the flow cross section of the measuring tube, while an outlet end of the flow conditioner facing the measuring tube accordingly has a flow cross section which is smaller than the flow cross section of the inlet end.

Especially in the US-A 58 08 209 as well as in the US-A 2005/0092101 is also noted in connection with the respective proposed flow conditioners that the thus realized transition between the two different sized flow cross sections steadily and by impurities, such as whirl-causing edges, must be kept absolutely clear.

This can be done by comparatively little processing of the surfaces of the flow conditioner as well as the possible existing in the inlet region of the measuring system joints are quite guaranteed to a satisfactory extent. However, it has been shown that despite the use of flow conditioners of the aforementioned type already minor disturbances of the flow in the inlet region of the measuring system, esp. Also in the actual measuring system upstream inlet segment of the connected process line or in the region of optionally serving for connection of inlet segment and measuring system inlet-side connecting flange, a significant variation of the flow conditions within the Meßrohrlumens and, consequently, a corresponding deterioration of the measurement accuracy are recorded.

A possibility To remedy this problem is superficial, a corresponding Processing of the inlet area of the measuring system, ie the inlet segment the process line or the inlet side flange connection make. Practically, however, this is hardly feasible, at least, however the user of the measuring system not without further ado. This in particular also because the Choice for the measuring system may also be due to the fact that in an existing system a previously installed, in terms of actual flow conditions but possibly oversized measuring system to be exchanged on an ad hoc basis. In that regard, so is the actual Installation situation for the measuring system not only as unpredictable, but also as practically not adaptable and to that extent as uncontrollable view.

A another possibility To circumvent this problem is also the installation length of the Strömunsgkonditionierers to enlarge, to so already in the flow conditioner a far - reaching stabilization and reassurance of the Flow, preferably So to achieve before their entry into the measuring tube. Indeed This can be a considerable increase the installation length of the entire measuring system to lead. With regard to the above mentioned Situation in which an existing conventional measuring system by such with upstream flow conditioner is to be replaced, the installation length for the measuring system is more or less fixed given and thus also an increase in the installation length of flow conditioner only possible in this rather limited extent. Given the disadvantages from conventional flow conditioners It is not surprising that the Scope of application of measuring systems which in speech Art is still regarded as rather limited.

A The object of the invention is therefore a measuring system for a streaming To create a medium, if possible short installation length an increase the Reynolds number of the flow from the process line to the measuring tube allows and still one opposite any possible disorders in the pouring Medium upstream of the measuring system, be it in the inflow segment and / or in the immediate transition area between process line and actual measuring system, largely insensitive measuring accuracy having.

• – einen Meßaufnehmer
• – mit einem dem Führen von zu messendem Medium dienenden, insb. im wesentlichen gerades, Meßrohr, das einen kleineren Strömungsquerschnitt aufweist, als ein einlaßseitig an das Meßsystem angeschlossenes Zulaufsegment der Prozeßleitung, und
• – mit einer Sensoranordnung,
• – die wenigstens ein primär auf die zu erfassende Meßgröße, insb. auch Änderungen derselben, reagierendes Sensorelement aufweist, und
• – die mittels des wenigstens einen Sensorelements wenigstens ein von der Meßgröße beeinflußtes Meßsignal liefert,
• – eine mit dem Meßaufnehmer kommunizierende Meßelektronik, die unter Verwendung des wenigstens einen Meßsignals zumindest zeitweise wenigstens einen die Meßgröße momentan repräsentierenden Meßwert, insb. einen Massendurchfluß-Meßwert, Volumendurchfluß-Meßwert, einen Dichte-Meßwert, einen Viskositäts-Meßwert, einen Druck-Meßwert, einen Temperatur-Meßwert, erzeugt, sowie
• – einen einlaßseitig des Meßrohrs angeordneten, zwischen diesem und dem Zulaufsegment der Prozeßleitung vermittelnden Strömungskonditionierer, der ein sich zum Meßrohr hin verjüngendes, im Betrieb vom Medium durchströmtes Lumen aufweist,
• – wobei ein dem Zulaufsegment der Prozeßleitung zugewandtes Einlaßende des Strömungskonditionierers einen Strömungsquerschnitt aufweist, der größer als der Strömungsquerschnitt des Meßrohrs ist, und ein dem Meßrohr zugewandtes Auslaßende des Strömungskonditionierers einen Strömungsquerschnitt aufweist, der kleiner als der Strömungsquerschnitt des Einlaßendes des Strömungskonditionierers ist, und
• – wobei im Strömungskonditioner wenigstens eine stromaufwärts des Auslaßendes des Strömungskonditionierers angeordnete, in dessen Lumen hineinragende, insb. entlang einer Mantellinie des Strömungskonditionierers umlaufende und/oder zirkuläre, Prallfläche vorgesehen ist, die im Betrieb von zu messendem Medium angeströmt ist.

To achieve the object, the invention consists in a in the course of a process line, esp. A pipeline, used measuring system for detecting at least one measured variable, esp. A mass flow, a volumetric flow, a flow rate, a density, a viscosity, a pressure, a temperature and / or the like, of a medium flowing in the process line, which measuring system comprises:

• - a transducer
• - Serving with a medium to be measured medium, esp. Essentially straight, measuring tube having a smaller flow area, as an inlet side connected to the measuring system inlet segment of the process line, and
• With a sensor arrangement,
• - Has at least one primarily on the measured variable to be detected, esp. Changes thereof, responsive sensor element, and
• - Which supplies by means of the at least one sensor element at least one of the measured variable influenced measuring signal,
• A measuring electronics communicating with the measuring transducer which, using the at least one measuring signal, at least temporarily present at least one measured value currently representing the measured variable, in particular a mass flow measured value, volume flow measured value, a density measured value, a viscosity measured value, a pressure measured value , a temperature reading, generated, as well
• A flow conditioner which is arranged on the inlet side of the measuring tube and mediates between the latter and the inlet segment of the process line and which has a lumen tapering towards the measuring tube and flowing through the medium during operation,
• Wherein an inlet end of the flow conditioner facing the inlet segment of the process line has a flow cross section which is greater than the flow cross section of the measuring tube, and an outlet end of the flow conditioner facing the measuring tube has a flow cross section which is smaller than the flow area of the inlet end of the flow conditioner, and
• - Wherein in the flow conditioner at least one upstream of the outlet end of the flow conditioner arranged, projecting into the lumen, esp. Along a generating line of the flow conditioner circumferential and / or circular, baffle surface is provided which has flowed in the operation of medium to be measured.

• – Strömenlassen des zu messen Mediums aus dem Zulaufsegment in den Strömungskonditionierer,
• – Aufstauen von in den Strömungskonditionierer einströmendem Medium und Induzieren wenigstens eines im wesentlichen stationären, insb. auch im wesentlichen ortsfesten, toroidalen Wirbels innerhalb von im Einlaßbereich des Strömungskonditionieres strömenden Medium in der Weise, daß eine größte gedachte Trägheitshauptachse des wenigstens einen toroidalen Wirbels mit der gedachten Längsachse des Strömungskonditionerers und/oder einer gedachten Längsachse des Meßrohrs im wesentlichen koinzidert,
• – Vorbeiströmenlassen von zu messem Medium an dem wenigstens einen toroidalen Wirbel und Strömenlassen von zu messendem Mediums aus dem Strömungskonditionierer in ein Meßrohr des angeschlossenen Meßaufnehmers, sowie
• – Erzeugen wenigstens eines von der zu erfassenden Meßgröße beeinflußten Meßsignals unter Verwendung wenigstens eine primär auf die Meßgröße, insb. auch Änderungen derselben, reagierendes Sensorelement.

Moreover, the invention consists in a method for detecting at least one measured variable, in particular a mass flow, a volume flow, a flow velocity, a density, a viscosity, a pressure, a temperature and / or the like of a medium flowing in a process line by means of a medium in the Course of the process line used measuring system having a flow conditioner connected to an inlet segment of the process line and a connected thereto transducer, which method comprises the following steps:

• Flowing the medium to be measured from the inlet segment into the flow conditioner,
• - Damming of inflowing into the flow conditioner medium and inducing at least one substantially stationary, esp. Also substantially stationary, toroidal vortex within flowing in the inlet region of the Strömungskonditionieres medium in such a way that a largest imaginary main axis of inertia of the at least one toroidal vortex with the imaginary The longitudinal axis of the flow conditioner and / or an imaginary longitudinal axis of the measuring tube substantially coincides,
• - Preflow of medium to be measured on the at least one toroidal vortex and flow of medium to be measured from the flow conditioner in a measuring tube of the connected transducer, and
• - Generating at least one of the measured variable to be detected measured signal using at least one primarily on the measured variable, esp. Changes thereof, responsive sensor element.

To a first embodiment of the measuring system of the invention provided that the Baffle so in the flow conditioner arranged and aligned that they at least in sections substantially perpendicular to an imaginary longitudinal axis of the flow conditioner and / or that they in sections substantially perpendicular to an imaginary longitudinal axis of the measuring tube runs.

To a second embodiment of the measuring system of the invention provided that the Baffle in radial direction a height which is at least 1 mm.

To a third embodiment of the measuring system of the invention provided that the Baffle as a circular ring surface is trained.

To a fourth embodiment of the measuring system of the invention provided that the Baffle and the inner edge at least partially by an inlet side in the flow conditioner Molded, in particular circular and / or self-contained, shoulder are formed.

To a fifth Design of the measuring system The invention provides that the impact surface at least partially formed substantially planar.

To a sixth embodiment of the measuring system of the invention provided that the baffle so in the flow conditioner is arranged and aligned so that they are coplanar in sections substantially to a cross section of the flow conditioner and / or that they in sections substantially coplanar to a cross section of the measuring tube is.

To a seventh embodiment of the measuring system of the invention provided that the baffle is formed at least partially substantially cone-shaped.

To an eighth embodiment of the measuring system of the invention provided that the Baffle itself to the measuring tube rejuvenating is trained.

To a ninth embodiment of the measuring system of the invention provided that the Baffle itself to the inlet end of the flow conditioner is formed widening towards.

To A tenth embodiment of the measuring system of the invention provided that the Baffle and the inner edge at least partially by an inlet side in the flow conditioner formed, in particular, extending to its inlet end, itself to the measuring tube rejuvenating Inner cone are formed.

To an eleventh embodiment of the measuring system of the invention provided that the the baffle of the flow conditioner forming inner cone has a flank angle greater than 45 °, especially larger than 60 °, is.

To a twelfth Design of the measuring system The invention provides that the baffle of the flow conditioner forming inner cone has a flank angle smaller than 90 °, esp. less than 88 °, is.

To A thirteenth embodiment of the measuring system of the invention provided that the the baffle of the flow conditioner forming inner cone has a flank angle greater than 60 ° and the is less than 88 °.

To a fourteenth embodiment of the measuring system of the invention provided that the Strömunsgkonditionierer at least in an inlet area is formed substantially circular cylindrical.

To a fifteenth Design of the measuring system The invention provides that the measuring tube at least in an inlet region is formed substantially circular cylindrical.

To a sixteenth embodiment of the measuring system of the invention provided that the Strömunsgkonditionierer at least in an outlet area is formed substantially circular cylindrical.

To a seventeenth embodiment of the measuring system of the invention provided that, esp. Circular cylindrical, measuring tube is essentially straight.

To an eighteenth embodiment of the measuring system of the invention provided that a Aspect ratio of the flow cross section the feed segment of the process line to the flow cross-section of the measuring tube greater than 1.5 is held.

To a nineteenth embodiment of the measuring system of the invention provided that a Aspect ratio of the flow cross section the feed segment of the process line to the flow cross-section of the measuring tube less than 10 is kept.

To a twentieth embodiment of the measuring system of the invention provided that a Aspect ratio of the flow cross section the feed segment of the process line to the flow cross-section of the measuring tube is kept in a range between 1.66 and 9.6.

To a twenty-first embodiment of the measuring system of the invention provided that the measuring tube a smaller caliber, as an inlet side of the measuring system Connected inlet segment of the process line.

To a twenty-second embodiment of the measuring system of the invention provided that the the inlet segment of the process line facing inlet end of the flow conditioner has a caliber larger than a caliber of the measuring tube is, and that the measuring tube facing outlet end of the flow conditioner a caliber smaller than the caliber of the inlet end of the flow conditioner is.

To a twenty-third embodiment of the measuring system of the invention provided that a caliber ratio of Caliber of the feed segment of the process line to the caliber of the measuring tube greater than 1.1 is held.

To a twenty-fourth embodiment of the measuring system of the invention provided that a caliber ratio of Caliber of the feed segment of the process line to the caliber of the measuring tube smaller is kept as 5.

To a twenty fifth Design of the measuring system The invention provides that a caliber ratio of Caliber of the feed segment of the process line to the caliber of the measuring tube in range between 1.2 and 3.1.

According to a twenty-sixth embodiment of the measuring system of the invention it is provided that the at least one sensor element by means of at least one piezoelectric and / or by means of at least a piezoresistive element is formed.

To a twenty-seventh embodiment of the measuring system of the invention provided that the at least one sensor element by means of at least one with a Anchor corresponding immersion coil is formed.

To a twenty-eighth embodiment of the measuring system of the invention provided that the at least one sensor element by means of at least one medium flowing in the measuring tube touching, electrical Potential measuring electrode is formed.

To a twenty-ninth embodiment of the measuring system of the invention provided that the at least one sensor element by means of at least one of changes the Meßgröße responsive Meßkondensators is formed.

To a thirtieth Design of the measuring system The invention provides that the at least one sensor element is formed by at least one electrical resistance.

To a thirty-first Design of the measuring system The invention provides that the at least sensor element in operation under the influence of the flowing medium in the measuring tube repeatedly mechanical Is subjected to deformations.

To a thirty-second Design of the measuring system The invention provides that the at least sensor element in operation repeatedly under the action of the medium flowing in the measuring tube relative moved to a static rest position.

To a thirty-third Design of the measuring system The invention provides that the transducer at least one in the measuring tube arranged bluff body includes.

To a thirty-fourth Design of the measuring system The invention provides that the at least one, esp. at least proportionally in the measuring tube protruding, sensor element of the sensor assembly downstream of the at least one bluff body is arranged.

To a thirty-fifth Design of the measuring system the invention provides that the measuring transducer as a vortex Durchflußaufnehmer, in particular a vortex flow sensor, is educated.

To a thirty-sixth Design of the measuring system The invention provides that the transducer as a magnetic-inductive flow sensor is trained.

To a thirty-seventh Design of the measuring system The invention provides that the transducer as a Durchflußaufnehmer of the vibration type, in particular around a Corilolis mass flow sensor, a density sensor, and / or a viscosity sensor, is trained.

To a thirty-eighth Design of the measuring system The invention provides that the transducer as an ultrasonic Durchflußaufnehmer is trained.

To a thirty-ninth Design of the measuring system the invention provides that the measuring tube has a fitting length, the bigger than an installation length of the flow conditioner is so that one Installation length ratio of installation length of the flow conditioner to the installation length of the measuring tube less than one is held.

To a fortieth embodiment of the measuring system of the invention provided that a caliber ratio the caliber of the feed segment of the process line to the caliber of the measuring tube at least 10% of the installation length ratios the installation length of the flow conditioner to the installation length of the measuring tube equivalent.

To a forty-first embodiment of the measuring system of the invention provided that at least a, in particular in operation immersed in the medium, sensor element at a distance from the inlet end of the measuring tube removed in and / or, esp. Immediately, is arranged on the measuring tube.

To a forty-second embodiment of the measuring system of the invention provided that at least a sensor element is placed so that a ratio of the distance to the caliber of the measuring tube greater than one is held.

To a forty-third embodiment of the measuring system of the invention provided that the baffle than a spherical one shaped and / or jagged, esp. Multiple serrated and / or corrugated, annular surface formed is.

To a first embodiment of the measuring system of the invention in the flow conditioner an upstream from its baffle arranged, guiding from in the flow conditioner flowing medium serving guide surface provided extending in the direction of the outlet end of the flow conditioner.

To a first embodiment of the first embodiment of the invention it is envisaged that the esp. Conically trained, guide surface of the Strömungskonditionieres at least Sectionally convex. According to a second embodiment the first development of the invention is provided that the, esp. conically formed, guide surface of the flow conditioner at least partially concave shaped. After a third Embodiment of the first development of the invention is provided that the baffle of the flow conditioner a substantially S-shaped Contour line has.

To a fourth embodiment of the first embodiment of the invention is provided that the baffle of the flow conditioner to the measuring tube rejuvenating is trained.

To a fifth Embodiment of the first development of the invention is provided that the baffle of the flow conditioner is substantially conically shaped.

To a sixth embodiment of the first embodiment of the invention is provided that the the baffle of the flow conditioner forming inner cone has a flank angle which is greater than 2 °, esp. greater than 4 °, as is.

To a seventh embodiment of the first invention is provided that the the guide surface of the flow conditioner forming inner cone has a flank angle smaller than 45 °, esp. smaller as 10 °, is.

To an eighth embodiment of the first embodiment of the invention is provided that the the Leiffläche of the flow conditioner forming inner cone has a flank angle greater than 4 ° and the is less than 10 °.

To A ninth embodiment of the first embodiment of the invention is provided that the baffle by one inlet side in the flow conditioner molded, extending in the direction of the inlet end first Inner cone and the Leiffläche through an inlet side in the flow conditioner molded, extending in the direction of the outlet end second Inner cone are formed. In particular, it is provided that the baffle forming first inner cone has a flank angle which is larger as a flank angle of the second inner cone forming the baffle surface. For example, you can the baffle of the flow conditioner forming first inner cone has a flank angle greater than 45 °, esp. greater than 60 °, and less than 90 °, especially smaller than 88 °, is, and the the guide surface of the flow conditioner forming second inner cone have a flank angle greater than 2 °, esp. greater than 4 °, and less than 45 °, esp. Less than 10 °, is.

To a second embodiment of the measuring system of the invention provided that the A flow at least one upstream from its outlet end arranged, projecting into the lumen of the flow conditioner, esp. Along a generatrix of the flow conditioner circumferential and / or circular, Inner edge, which in operation of the guided medium flows against is.

To a first embodiment of the second embodiment of the invention is provided that the at least one projecting into the lumen of the flow conditioner Inner edge formed and arranged in the flow conditioner is, that you essentially transversely to an imaginary longitudinal axis of the flow conditioner and / or aligned transversely to an imaginary longitudinal axis of the measuring tube is.

According to a second embodiment of the second embodiment of the invention it is provided that the at least one projecting into the lumen of the flow conditioner inner edge, esp. Circular, circumferentially and so far closed in itself is formed.

To a third embodiment of the second embodiment of the invention is provided that the at least one projecting into the lumen of the flow conditioner Inner edge in, especially immediate, near the inlet end of flow conditioner is arranged.

To a fourth embodiment of the second embodiment of the invention is provided that the at least one projecting into the lumen of the flow conditioner Inner edge immediately at the inlet end of the flow conditioner is arranged.

To a fifth Embodiment of the second embodiment of the invention is provided that the at least one projecting into the lumen of the flow conditioner Inner edge has an edge radius of less than 2 mm, esp. smaller 0.6 mm, is.

To a sixth embodiment of the second embodiment of the invention is provided that the inner edge has a serrated or wavy contour.

To a seventh embodiment of the second embodiment of the invention it is envisaged that one of the at least one projecting into the lumen of the flow conditioner Inner edge of limited cross-section of the lumen of the flow conditioner smaller than the flow cross-section the feed segment of the process line.

To an eighth embodiment of the second embodiment of the invention is provided that a Constriction ratio of through the inner edge of limited cross section to the flow cross section the feed segment of the process line is kept smaller than 0.9.

To a ninth embodiment of the second embodiment of the invention is provided that a constriction of the through the inner edge of limited cross section to the flow cross section the feed segment of the process line greater than 0.1 is held.

To a tenth embodiment of the second embodiment of the invention is provided that a constriction of the through the inner edge of limited cross section to the flow cross section the feed segment of the process line is maintained in a range between 0.25 and 0.85.

To an eleventh embodiment of the second embodiment of the invention is provided that a contraction ratio of the limited by the inner edge cross-section to the flow cross-section of the measuring tube greater than 1.2 is held. After a twelfth Embodiment of the second embodiment of the invention is provided the existence contraction ratio of the limited by the inner edge cross-section to the flow cross-section of the measuring tube less than 5 is kept. After a thirteenth embodiment the second embodiment of the invention it is provided that a contraction ratio of the through the inner edge of limited cross section to the flow cross section of the measuring tube is maintained in a range between 1.3 and 3.

To a fourteenth embodiment of the second embodiment of the invention is provided that a Difference between a cross-sectional ratio of the flow cross section the feed segment of the process line to the flow cross-section of the measuring tube and a necking ratio of through the inner edge of limited cross section to the flow cross section the feed segment of the process line greater than 0.5 is held.

To a fifteenth Embodiment of the second embodiment of the invention is provided that one Difference between a cross-sectional ratio of the flow cross section the feed segment of the process line to the flow cross-section of the measuring tube and a necking ratio of through the inner edge of limited cross section to the flow cross section the feed segment of the process line less than 10 is kept.

To a sixteenth embodiment of the second embodiment of the invention is provided that a Difference between a cross-sectional ratio of the flow cross section the feed segment of the process line to the flow cross-section of the measuring tube and a necking ratio of through the inner edge of limited cross section to the flow cross section the feed segment of the process line greater than 0.83 and less than 9.5.

To a seventeenth embodiment of the second embodiment of the invention is provided that a Difference between a cross-sectional ratio of the flow cross section the feed segment of the process line to the flow cross-section of the measuring tube and a contraction ratio of the limited by the inner edge cross-section to the flow cross-section of the measuring tube greater than 0.2 is held.

To an eighteenth embodiment of the second embodiment of the invention is provided that a Difference between a cross-sectional ratio of the flow cross section the feed segment of the process line to the flow cross-section of the measuring tube and a contraction ratio of the limited by the inner edge cross-section to the flow cross-section of the measuring tube less than 10 is kept.

To a nineteenth embodiment of the second embodiment of the invention is provided that a Difference between a cross-sectional ratio of the flow cross section the feed segment of the process line to the flow cross-section of the measuring tube and a contraction ratio of the limited by the inner edge cross-section to the flow cross-section of the measuring tube greater than 0.25 and less than 8 is held.

To a twentieth embodiment of the second embodiment of the invention is provided that the at least one projecting into the lumen of the flow conditioner Inner edge is formed by the inner diameter of the inlet end of the flow conditioner is smaller than the caliber of the feed segment of the process line.

To a twenty-first embodiment of the second development the invention provides that one of the at least one into the lumen of the flow conditioner projecting inner edge limited cross section of the lumen of flow conditioner has a diameter smaller than the caliber of the Feed segment of the process line.

To a twenty-second embodiment of the second development The invention provides that the at least one in the Lumen of the flow conditioner protruding inside edge of a leading in the flow conditioner pouring Medium serving, in the direction of the outlet end of the flow conditioner extending guide surface of the flow conditioner limited.

To a twenty-third embodiment of the second development The invention provides that the at least one in the Lumen of the flow conditioner projecting inner edge of the damming of inflowing medium serving, in one, especially circular circumferential, edge region of the flow conditioner arranged impact surface of the flow conditioner limited.

To a twenty-fourth embodiment of the second development The invention provides that the at least one in the Lumen of the flow conditioner projecting inner edge of the damming of inflowing medium serving, in one, especially circular circumferential, edge region of the flow conditioner arranged impact surface of the flow conditioner as well as a leading of in the flow conditioner pouring Medium serving, in the direction of the outlet end of the flow conditioner extending guide surface of the flow conditioner limited.

To a third embodiment of the measuring system of the invention provided that the A flow at least one upstream from its outlet end arranged, projecting into the lumen of the flow conditioner, esp. Along a generatrix of the flow conditioner circumferential and / or circular, Inner edge, which in operation of the guided medium flows against is, and that in the A flow an upstream from its baffle arranged, guiding from in the flow conditioner pouring Medium serving guide surface is provided which extends in the direction of the outlet end of the flow conditioner extends, wherein the guide surface and the inner edge at least partially by an inlet side in the flow conditioner molded, esp. extending to the outlet end, inner cone are formed.

To A first embodiment of the method of the invention comprises the step of damming into the flow conditioner inflowing Medium further includes a step of flowing medium to a medium the pouring Medium in one, esp. Along a generatrix of the flow conditioner closed circumferential, opposing edge region of the flow conditioner Baffle of the flow conditioner for inducing the at least one substantially stationary toroidal vertebra in the inlet area of the flow conditioner.

To A second embodiment of the method of the invention comprises this further steps of accelerating fluid flowing in the flow conditioner in the direction of an imaginary longitudinal axis of the flow conditioner.

To A third embodiment of the method of the invention comprises the step inducing the at least one substantially stationary toroidal Vertebrae in the inlet area of the flow conditioner Steps of passing by of medium at a projecting into a lumen of the Strömungsungskonditionieres, esp. Along one of its generatrices closed encircling, Inner edge of the flow conditioner.

To A fourth embodiment of the method of the invention comprises this Further, a step of inducing at least one other essentially stationary, esp. Essentially stationary, toroidal vortex in the inlet area of the flow conditioner in such a way that the largest imaginary Principal axis of inertia each at least two toroidal vertebrae substantially together koinzideren. According to a development of this embodiment of the invention is provided that at least one of the steps of inducing substantially stationary toroidal Whirling in the inlet area the flow conditioner steps of passing by of medium at a projecting into a lumen of the Strömungsungskonditionieres, esp. Along one of its generatrices closed encircling, Inner edge of the flow conditioner includes.

One The basic idea of the invention is the measuring accuracy of measuring systems the type described not only to improve the fact that the flow sufficient accelerated and thus safe in a favorable Reynolds number range is transformed, but also by the fact that on the one hand possibly upstream of the measuring system registered in the current disorders, such as. in the pipe wall near edge regions "floating" vortex, by means of the actual transducer upstream flow conditioner largely eliminate and thus on the other hand by means of the flow conditioner largely insensitive to disturbances, for the Measuring principle sufficiently well reproducible flow profile for the in the transducer incoming Adjust medium immediately before this.

This takes place in the measuring system according to the invention in particular by the fact that in its inlet region at least one substantially toroidaler Whirl is generated, at least in a steady state largely kept stationary. This stationary vortex acts for the passing medium practically as an extra Cross-sectional narrowing and thus effectively as a "virtual" nozzle, the within the streaming Medium is formed intrinsically.

A special feature of such a "virtual" nozzle consists i.a. in that she disturbances possibly induced in the flow before the inlet area eliminated and above downstream of a largely undisturbed flow profile practically rebuilt. It fits the size and strength of the toroidal Wirbels fortunately even at the size and strength of the incoming disturbance, So that the thus created "virtual" nozzle practically in the sense of effective troubleshooting self-adapting.

The Invention is based on the surprising Realization that one such stationary, esp. Also largely stationary, vortex by means of a in the inlet area of the measuring system placed, in an edge region of the lumen flowed through by the medium as a defined disorder acting flow obstacle - here one preferably streamed frontal and as possible Completely, in particular circular, circumferential impact surface - to be achieved can.

The Effect of the generated by the toroidal vortex "virtual" nozzle can be In addition, thereby further improve that downstream of the generated before the baffle Vortex another, equally stationary as possible vortex in the A flow is stationed, possibly also immediately behind the first Whirl. This can be constructive in the flow conditioner according to the invention a very simple way be achieved in that further a limiting the baffle, esp. equally circular circulating, sharp inner edge is provided on the flowing medium in a for the vortex formation acts sufficiently as a tear-off edge.

By forming two such toroidal, esp. Also largely mutually concentric aligned eddies on the one hand in the inflowing medium mitschwimmende eddies can be better absorbed and thus eliminated more effectively. On the other hand, by means of two such concentric vortices standing one behind the other, the effectively effective contour of the "virtual" nozzle thus formed becomes practically one Approached S-shape, which favors the formation of a very suitable for the subsequent measurement, equally well over a wide range of applications well reproducible flow profile. Thus, despite any disturbed flow in the inlet segment, the measuring transducer can be supplied via the flow conditioner with medium having such a flow profile, which is at least largely similar to a calibrated situation.

The Use of a flow conditioner according to the present The invention has, for example, in the aforementioned Vortex measuring devices u.a. also the advantage that they despite comparatively large differences between the caliber of the inlet segment of the connected process line and the caliber of the measuring tube, e.g. above two nominal nominal diameter steps, also for the measurement of comparatively slowly pouring Gases are suitable. This in particular also because of this Way at least for that measuring volume, esp. also for in the inlet area of the measuring system first disturbed Airfoils a far-reaching independence the Strouhal number over the Meßrohrquerschnitt can be created.

1 shows a perspective view in a side view of a measuring system for a medium flowing in a process line,

2 . 3 show one for use in a measuring system according to

1 suitable, vortex-based vortex transducer, and

4 to 8th show schematically in cross-section details of the measuring system according to 1 ,

In the 1 is an optionally modular design, measuring system shown schematically, which is suitable and intended, at least one measured variable, esp. A mass flow m and / or volumetric flow v and / or a flow velocity u and / or another flow parameter in one - here not shown - process line flowing medium, such as a liquid, a gas, a vapor or the like, to measure very robust and to map in at least one corresponding measured value X _M. The measuring system for this purpose comprises at least one in-line measuring device for flowing media, by means of a corresponding Meßaufnehmers 100 as well as with this at least temporarily electrically coupled measuring electronics of the measuring system is formed. The in-line measuring device comprises a measuring transducer through which the medium to be measured flows during operation 100 as well as an electronics housing 200 in which one with the transducer 100 electrically connected - not shown here - measuring electronics is housed.

The transducer 100 has at least one in the course of, esp. Designed as a pipe, process line inserted measuring tube through which at least temporarily the medium to be measured is allowed to flow through during operation of the measuring system. The in-line measuring device is in particular intended to generate at least temporarily at least one measuring signal which is dependent on at least one physical parameter, in particular a flow velocity, a mass flow rate m, a volume flow rate v, a density ρ and / or a viscosity η, of the medium located in the measuring tube is influenced and corresponds to the extent corresponding to the measured variable. To generate the at least one measuring signal, a sensor arrangement of the in-line measuring device is provided on the measuring tube and / or in its vicinity which reacts at least indirectly to changes in the at least one measured variable of the medium in a manner correspondingly influencing the at least one measuring signal.

According to an advantageous embodiment of the invention, the measuring electronics is further designed so that in operation the measuring system with a higher-level measured value processing unit, such as a programmable logic controller (PLC), a personal computer and / or a workstation, via data transmission system, for example, a fieldbus system, measuring and / or other operating data, in particular also the at least one measured value X _M , can exchange. For this aforementioned case, that the measuring system is provided for coupling to a fieldbus or other communication system, the meter electronics on a corresponding communication interface for data communication, eg for sending the measured data to the aforementioned programmable logic controller or a higher-level process control system, on. Also for this purpose, for example, in the industrial measuring and automation technology according to established standard interfaces can be used. In addition, the external power supply can be connected to the fieldbus system and supply the measuring system in the manner described above with energy directly via fieldbus system.

In the embodiment shown here, a vortex flow meter serves as an in-line meter, the As is known, it is well suited for the measurement of gases to detect the physical measured quantity, in particular the mass flow rate m, the density ρ and / or the viscosity η, of the medium to be measured with high precision. However, other in-line meters equally well established in process automation technology may be used to determine the measurand, such as magnetic inductive flowmeters, Coriolis flowmeters, thermal flowmeters, differential pressure flowmeters, ultrasonic flowmeters, or the like.

The in the 2 and 3 shown and used in the overview perspective views of an embodiment of a vortex transducer according to the vortex principle, on the one hand seen in the flow direction ( 2 ) and on the other hand seen against the flow direction ( 3 ), a partially cut Meßsaufnehmer 1 a vortex flow meter with one on a pipe wall 21 a measuring tube 2 fixed and through a hole 22 protruding vortex sensor 3 , This can, for example, a dynamically compensated vortex sensor with a capacitive sensor element, as in the US-A 60 03 384 is described.

Along a diameter of the measuring tube 2 is in its interior a baffle 4 arranged with the measuring tube 2 forming a illustrated first fixation site 41 and a hidden second fixation site 41 * is firmly connected. The center of the hole 22 and the center of the fixation site 41 lie on a generatrix of the measuring tube 2 ,

The baffle body 4 has a baffle 42 , against which a medium to be measured, eg. As a liquid, a gas or a vapor, flows to. The baffle body 4 also has two side surfaces, of which only one (front) side surface 43 in the 1 and 2 you can see. From the baffle 42 and the side surfaces are formed two tear-off edges, of which only one (front) tear-off edge 44 completely and a (rear) spoiler lip 45 hinted at 1 you can see.

The baffle body 4 of the 1 and 2 has substantially the shape of a straight triangle column, so a column with a triangular cross-section. However, other common forms of bluff body may be used in the invention.

By the flow of the medium against the baffle 42 Forms downstream of the bluff body 4 in the known manner, a Kärmän'sche vortex street characterized in that at each trailing edge alternately tear off the vortex and taken away from the flowing medium. These vortices produce local pressure fluctuations in the flowing medium whose time-related demolition frequency, ie their so-called vortex frequency, is a measure of the flow velocity and / or the volume flow rate of the medium.

The pressure fluctuations are by means of the vortex sensor 3 converted into a serving as an electrical measurement signal vortex signal, which housed a housed in the electronics housing - but not shown here and not explained in more detail - measuring electronics is supplied from the calculated, for example, the flow rate and / or the volumetric flow of the flowing medium accordingly.

The vortex sensor 3 is downstream of the bluff body 4 into the hole 22 the pipe wall 21 of the measuring tube 2 inserted and seals the hole 22 to the lateral surface of the measuring tube 2 down to what the vortex sensor 3 with the pipe wall 21 is screwed. For this purpose serve z. B. four screws, of which in the 1 and 2 the screws 5 . 6 . 7 are seen while in 3 associated holes 50 . 60 . 70 . 80 are shown.

From the vortex sensor 3 is one in the 1 and 2 into the interior of the measuring tube 2 through the hole 22 the pipe wall 21 protruding wedge-shaped sensor flag 31 and a housing cap 32 to see. The housing cap 32 runs with the insertion of a thin-walled intermediate piece 323 in an extension 322 out, cf. the mentioned US-A 60 03 384 ,

The sensor flag 31 has major surfaces, of which in the 1 and 2 only the main area 311 you can see. The main surfaces are aligned with the aforementioned generatrix of the measuring tube 2 and form a front edge 313 , The sensor flag 31 may also have other suitable spatial forms; so she can z. B. have two parallel major surfaces that form two parallel front edges.

The sensor flag 31 is shorter than the diameter of the measuring tube 2 ; it is also rigid and has a blind hole 314 on (only in 4 to see). So that the blind hole 314 has a sufficient diameter, emerge from the main surfaces wall parts, of which 3 the wall part 315 is indicated. The bag hole 314 extends to near the front edge 313 and has a floor there.

To the vortex sensor 3 further includes a bore 22 covering membrane 33 with a medium facing the first surface 331 and a second surface facing away from the medium 332 , see the 3 and 4 , On the surface 331 is the sensor flag 31 fixed and on the surface 332 a sensor element 36 , Preference is given to the sensor flag 31 , the membrane 33 whose annular edge 333 and at the membrane 33 attached part 361 of the sensor element 36 from a single piece of material, for. As metal, esp. Stainless steel. The sensor element 36 generates the above-mentioned signal whose frequency is proportional to the volume flow of the flowing medium.

In the measuring system according to the invention, the measuring medium serving to guide, in particular substantially straight, measuring tube has a smaller flow cross-section A1, as an inlet side connected to the measuring system inlet segment 400 the process line. Therefore, the measuring system further comprises an inlet side of the measuring tube arranged between this and the inlet segment of the process line mediating flow conditioner 300 , the one to the measuring tube 2 has tapered, flowing in the operation of the medium lumen. An inlet end of the flow conditioner facing the inlet segment of the process line has a flow cross section a which is greater than the flow cross section A1 of the measuring tube, while an outlet end of the flow conditioner facing the measuring tube has a flow cross section which is smaller than the flow cross section of the inlet end of the flow conditioner. In the measuring operation, the medium to be measured from the inlet segment is flowed into the flow conditioner and accelerated due to the decreasing flow cross-section in the direction of the imaginary longitudinal axis of the flow conditioner.

At the Measuring system according to the invention indicates the flow conditioner further at least one upstream of the outlet end thereof, into the lumen of the flow conditioner protruding, esp. Along a generatrix of the flow conditioner circumferential and / or circular, baffle P on. The baffle is designed and arranged in the flow conditioner, that she from that in the measuring mode into the flow conditioner pour in left medium first flowed in frontal is. Due to abrupt or abrupt on the baffle P decreasing flow cross-section becomes the oncoming Medium dammed up there. As a result, upstream of the baffle P finally forms essentially toroidal, at least in the stationary state largely stationary first vortex w2, in its dimensions on the one hand by the Einlaßgeometrie the flow conditioner, esp. Also its baffle, and on the other by the flowing Medium itself is determined. Practically, therefore, by the Vortex w2 in the inlet area of the flow conditioner a nozzle formed virtually, not only largely continuous in their contours is but, in addition, itself to the actual flow optimally adapts. For the through the vortex w2 further flowing medium acts this at least to the extent as for stabilizing the following self-adjusting flow profile as a whole, as he passes through the baffle P first caused jumpy cross-sectional tapering substantially steadily compensates and thus in a gentle, but nevertheless the flow further accelerating cross-sectional reduction transferred. The baffle P is according to a Embodiment of the invention further arranged in the flow conditioner and aligned that they at least in sections substantially perpendicular to an imaginary Longitudinal axis of the flow conditioner and / or that they substantially perpendicular to an imaginary longitudinal axis of the feed segment runs. As a result, the first vortex w2 becomes within the inlet area of the flow conditioner flowing Medium advantageously designed so that a largest imaginary main inertia axis of this vortex w2 with the imaginary longitudinal axis of the flow conditioner and / or an imaginary longitudinal axis of the feed segment is substantially coincident. Because especially Good results, especially with regard to location stability and reproducibility of the vortex w2, achieved with a pronounced baffle P. can be this has an advantageous embodiment of the invention in the radial direction, a height h2, which is at least 1 mm. The baffle P may, for example, as a substantially planar annular surface or also cone-shaped, to the measuring tube rejuvenating or for process control be widened towards expanding. In the embodiment shown here is the baffle P also in the immediate vicinity of the inlet end of the flow conditioner arranged.

According to one embodiment of the invention, the flow conditioner in addition to the aforementioned baffle P on a downstream of this arranged vortex-releasing inner edge K. For the above-described case in which the medium flows through the flow conditioner, downstream of the inner edge K, in addition to the first vortex w2, there likewise forms a substantially toroidal second vortex w1, which is equally largely stationary at least in the stationary state. The inner edge K is designed according to a further embodiment of the invention for this purpose and arranged in the flow conditioner that they are in essence aligned transversely to an imaginary longitudinal axis of the flow conditioner and / or transversely to an imaginary longitudinal axis of the measuring tube. Furthermore, the inner edge K, esp. Circular, circumferentially and so far closed in itself.

in the embodiment shown here is due to the positioning of the baffle P in the, esp. Immediate, Near the inlet end of the flow conditioner also arranged the inner edge K in the inlet region. That I particularly good results with a pronounced, comparatively sharp Inner edge can be achieved, this has an edge radius in an advantageous embodiment on, which is smaller than 2 mm, esp. Less than 0.6 mm.

to further improvement of the flow profile It may also be beneficial to have the baffle shaped as a spherical one and / or jagged, esp. Jagged, or undulating annular surface and / or the inner edge form with serrated or wavy contour, creating a still further reinforced Mixing of the on or passing medium and insofar an even more drastic rearrangement of the airfoil can be achieved can.

Like from the 4 it can be seen, the inner edge K generating the second vortex w1 is formed by abutment of the impact surface P practically instantaneously, ie without gentle or steady balance, on a surface L which extends in the direction of the outlet end of the flow conditioner and guides medium flowing in the flow conditioner , which is therefore also limited by the inner edge K so far. The tapered to the measuring tube guide surface L can, for example, as well as in the 4 to 8th shown to be substantially conically shaped, esp. So that at least partially convex and / or sections concave, for example, a substantially S-shaped contour line ( 7 ) having. In the embodiment shown here, the baffle P and, to that extent, the inner edge K is also formed in a simple manner that the inner diameter of the inlet end of the flow conditioner is kept smaller than the caliber of the feed segment of the process line.

The Inner edge K is according to a further embodiment of the invention also designed so that in the passing it Medium the second vortex w1 is formed in such a way that a largest imaginary Principal axis of inertia of the vortex w1 with the imaginary longitudinal axis of the flow conditioner and / or an imaginary longitudinal axis of the measuring tube essentially coincident. For that flows past whirls w1 Medium affects this both cross-sectional narrowing as well to the Leiffläche L mediating and so far for the flow profile stabilizing.

For the here shown case that at least another essentially stationary, largely stationary toroidal vortex in the inlet area of the flow conditioner is induced, results in addition to the gentle reduction of the cross section created by the first vortex w2 effectively an additional, equally steady cross-sectional constriction and, to that extent, even more increased acceleration by the in the inlet area stationed toroidal vortex flowing medium, accompanying with an increase from its Reynolds number. In the configuration shown here measurement system at the lumen of the Strömungskondiditionieres through one about its longitudinal axis defined essentially rotationally symmetric cone and the longitudinal axes of the feed segment and the flow conditioner essentially coincide with each other, the two form Whirl w2, w1 so that the largest imaginary Principal axis of inertia each of the two vortices w1, w2 substantially coincide with each other. This in turn leads to that in Advantageously, the thus virtually formed in the inlet area Nozzle with respect to the longitudinal axis of the flow conditioner is largely rotationally symmetric. This has u.a. the advantage, that this by means of such a nozzle formed flow profile is also largely rotationally symmetric. This in turn can be achieved that esp. in the connected measuring tube, the Strouhal number over the pipe cross-section seen is kept substantially constant. In order to can go along on the one hand, the flow conditions in the medium to be measured a wide range of applications stable and therefore easy to reproduce or be kept predictable. For another, so too for many Applications with input-side disturbed flow profiles of one Strouhalzahl gone out over a wide range of application in good nutrition is kept constant or only changes in a known manner depending on the Reynolds number.

A1

– Strömungsquerschnitt des Meßrohrs,

A2

– Strömungsquerschnitts des Zulaufsegments der Prozeßleitung,

A2/A1

– Querschnittsverhältnis des Strömungsquerschnitts A2 des Zulaufsegments der Prozeßleitung zum Strömungsquerschnitt A1 des Meßrohrs,

a

– von der Innenkante K begrenzter Querschnitt des Lumens des Strömungskonditionierers,

a/A1

– Kontraktionsverhältnis des durch die Innenkante begrenzten Querschnitts a zum Strömungsquerschnitt A1 des Meßrohrs,

A2/A1-a/A1

– Differenz zwischen dem Querschnittsverhältnis A2/A1 und dem Kontraktionsverhältnis a/A1,

a/A2

– Einschnürungsverhältnis des durch die Innenkante begrenzten Querschnitts a zum Strömungsquerschnitt A2 des Zulaufsegments der Prozeßleitung,

A2/A1-a/A2

– Differenz zwischen dem Querschnittsverhältnis A2/A1 und dem Einschnürungsverhältnis a/A2,

D1

– Kaliber des Meßrohrs,

D2

– Kaliber des Zulaufsegments der einlaßseitig an das Meßsystem angeschlossen Prozeßleitung,

D2/D1

– Kaliberverhältnis des Kaliber D2 des Zulaufsegments der Prozeßleitung zum Kaliber D1 des Meßrohrs,

d

– Durchmesser des durch die Innenkante K begrenzten Querschnitts des Lumens des Strömungskonditionierers,

L1

– Einbaulänge des Meßrohrs,

L2

– Einbaulänge des Strömungskonditionierers,

Lm

– Abstand des Sensorelements vom Einlaßende des Meßrohrs,

α

– Flankenwinkel eines die Prallfläche des Strömungskonditionieres bildenden Innenkonus (a = 90° – a_⊥),

β

– Flankenwinkel eines die Leitfläche des Strömungskonditionieres bildenden Innenkonus,

Further advantageous embodiments and special embodiments, esp. Also found to be advantageous found dimensions for the individual elements of the flow conditioner according to the invention are listed in the following tables 1, 2 as well as in the following claims, wherein, inter alia:

A1

Flow cross-section of the measuring tube,

A2

Flow cross-section of the feed segment of the process line,

A2 / A1

Cross section ratio of the flow cross section A2 of the feed segment of the process line to the flow cross section A1 of the measuring tube,

a

A cross-section of the lumen of the flow conditioner bounded by the inner edge K,

a / A1

Contraction ratio of the cross section a delimited by the inner edge to the flow cross section A1 of the measuring tube,

A2 / A1-a / A1

Difference between the aspect ratio A2 / A1 and the contraction ratio a / A1,

a / A2

Constriction ratio of the cross section a delimited by the inner edge to the flow cross section A2 of the feed segment of the process line,

A2 / A1-a / A2

Difference between the aspect ratio A2 / A1 and the necking ratio a / A2,

D1

- caliber of the measuring tube,

D2

Caliber of the inlet segment of the process line connected to the measuring system on the inlet side,

D2 / D1

Caliber ratio of the caliber D2 of the feed line of the process line to the caliber D1 of the measuring tube,

d

The diameter of the cross-section of the lumen of the flow conditioner bounded by the inner edge K,

L1

- installation length of the measuring tube,

L2

- installation length of the flow conditioner,

Lm

Distance of the sensor element from the inlet end of the measuring tube,

α

Flank angle of an inner cone forming the baffle surface of the flow conditioner (a = 90 ° - a _⊥ ),

β

Flank angle of an inner cone forming the guide surface of the flow conditioner,

Claims (86)

In the course of a process management, esp. A pipeline, used measuring system for detecting at least a measurand, esp. a mass flow, a volume flow, a flow velocity, a density, a viscosity, a pressure, a temperature and / or the like, one in the process line flowing Medium, which measuring system comprising: - one transducer - with a the lead serving medium to be measured, esp. Essentially straight, measuring tube, that a smaller flow area (A1), as an inlet side to the measuring system connected inlet segment of the process line, and - with a Sensor array, - the at least one primary on the measured variable to be detected, esp. also changes has the same, responsive sensor element, and - the means the at least one sensor element supplies at least one measurement signal influenced by the measured variable, - one with the transducer communicating measuring electronics, the at least temporarily using the at least one measurement signal at least one the measured variable currently representing Measured value, esp. a mass flow rate, volume flow rate, a Density measured value, a viscosity reading, a Pressure measured value, a temperature reading or the like, generated, as well as - one inlet side of the measuring tube arranged, mediating between this and the inlet segment of the process line flow conditioner, the one to the measuring tube rejuvenating, during operation of the medium flowed through Having lumens, - in which a the inlet segment of the process line facing inlet end of the flow conditioner a flow cross-section (a) which is greater than the flow cross section (A1) of the measuring tube is, and a measuring tube facing outlet end of the flow conditioner a flow cross-section (b) smaller than the flow area of the inlet end of the flow conditioner is and - in which in the flow conditioner at least one upstream the outlet end of the flow conditioner arranged, projecting in the lumen, esp. Along a Generating line of the flow conditioner circumferential and / or circular, baffle is provided, which has flowed in the operation of medium to be measured. measuring system according to the previous claim, wherein the baffle surface so in the flow conditioner arranged and aligned so that they at least partially substantially perpendicular to an imaginary longitudinal axis of the flow conditioner and / or that they in sections substantially perpendicular to an imaginary longitudinal axis of the measuring tube runs. measuring system according to one of the preceding claims, the baffle has a height in the radial direction, which is at least 1 mm. measuring system according to one of the preceding claims, the baffle as a circular ring surface is trained. measuring system according to one of the preceding claims, the baffle as a spherical one shaped and / or jagged, esp. Multiple serrated and / or corrugated, annular surface formed is. measuring system according to one of the preceding claims, the flow conditioner at least in an inlet area is formed substantially circular cylindrical. measuring system according to one of the preceding claims, the measuring tube at least in an inlet area is formed substantially circular cylindrical. measuring system according to the preceding claim, wherein the flow conditioner at least in an outlet area is formed substantially circular cylindrical. measuring system according to one of the preceding claims, wherein the, esp. circular cylindrical, measuring tube is substantially straight is. measuring system according to one of the preceding claims, where a cross-sectional ratio (A2 / A1) of the flow cross-section (A2) of the feed segment of the process line to the flow cross-section (A1) of the measuring tube is greater than 1.5 is held. measuring system according to one of the preceding claims, where a cross-sectional ratio (A2 / A1) of the flow cross-section (A2) of the feed segment of the process line to the flow cross-section (A1) of the measuring tube smaller is kept as 10. measuring system according to one of the preceding claims, where a cross-sectional ratio (A2 / A1) of the flow cross-section (A2) of the feed segment of the process line to the flow cross-section (A1) of the measuring tube in a range between 1.66 and 9.6 is maintained. measuring system according to one of the preceding claims, the baffle at least partially formed substantially planar. measuring system according to the previous claim, wherein the baffle surface so in the flow conditioner arranged and aligned so that they are in sections substantially Coplanar to a cross section of the flow conditioner and / or that she in sections substantially coplanar to a cross section of the measuring tube is. measuring system according to one of the preceding claims, the baffle is formed at least partially substantially cone-shaped. measuring system according to one of the preceding claims, the baffle to the measuring tube rejuvenating is trained. measuring system according to one of the preceding claims, the baffle to the inlet end of the flow conditioner is formed widening towards. measuring system according to one of the preceding claims, the flow conditioner at least one upstream from its outlet end arranged, projecting into the lumen of the flow conditioner, esp. Along a generatrix of the flow conditioner circumferential and / or circular, Inner edge, which in operation of the guided medium flows against is. measuring system according to claim 18, wherein the at least one into the lumen of flow conditioner protruding inner edge so formed and in the flow conditioner that is arranged essentially transversely to an imaginary longitudinal axis of the flow conditioner and / or aligned transversely to an imaginary longitudinal axis of the measuring tube is. measuring system according to claim 18 or 19, wherein the at least one into the lumen of the flow conditioner protruding inner edge, esp. Circular, circumferentially and so far in is formed closed. measuring system according to one of the claims 18 to 20, wherein the at least one in the lumen of the flow conditioner projecting inside edge in the, in particular immediate, proximity of the inlet end of flow conditioner is arranged. measuring system according to one of the claims 18 to 21, wherein the at least one in the lumen of the flow conditioner protruding inner edge disposed directly at the inlet end of the flow conditioner is. measuring system according to one of the claims 18 to 22, with the baffle and the inner edge at least partially by an inlet side in the flow conditioner Molded, in particular circular and / or self-contained, shoulder are formed. measuring system according to one of the claims 18 to 23, wherein the at least one in the lumen of the flow conditioner protruding inner edge has an edge radius, the smaller than 2 mm, esp. Less than 0.6 mm. measuring system according to one of the claims 18 to 24, with the inner edge of a serrated or wavy contour having. Measuring system according to one of claims 18 to 25, wherein one of the at least one projecting into the lumen of the flow conditioner inner edge limited cross-section (a) of the lumen of Strö mungskonditionierers is smaller than the flow cross-section (A2) of the feed segment of the process line. measuring system according to claim 26, wherein a constriction ratio (a / A2) of the by the Inner edge of limited cross section (a) to the flow cross-section (A2) of the inlet segment the process line is kept smaller than 0.9. measuring system according to claim 26 or 27, wherein a constriction ratio (a / A2) of the by the Inner edge of limited cross section (a) to the flow cross-section (A2) of the inlet segment the process line greater than 0.1 is held. measuring system according to one of the claims 26 to 28, wherein a necking ratio (a / A2) the limited by the inner edge cross-section (a) to the flow cross-section (A2) of the feed segment of the process line in a range between 0.25 and 0.85 is held. measuring system according to one of the claims 10 to 12 and one of the claims 27 to 29, wherein a difference (A2 / A1-a / A2) between the aspect ratio (A2 / A1) and the necking ratio (a / A2) is greater than 0.5 is held. measuring system according to one of the claims 10 to 12 in conjunction with any of claims 27 to 29, wherein a difference (A2 / A1-a / A2) between the aspect ratio (A2 / A1) and the necking ratio (a / A2) less than 10 is kept. measuring system according to one of the claims 10 to 12 in conjunction with any of claims 27 to 29, wherein a difference (A2 / A1-a / A2) between the aspect ratio (A2 / A1) and the necking ratio (a / A2) greater than 0.83 and less than 9.5. measuring system according to one of the claims 26 to 32, wherein a contraction ratio (a / A1) of the by Inner edge of limited cross-section (a) to the flow cross-section (A1) of the measuring tube greater than 1.2 is held. measuring system according to one of the claims 26 to 33, wherein a contraction ratio (a / A1) of the by Inner edge of limited cross-section (a) to the flow cross-section (A1) of the measuring tube smaller is kept as 5. measuring system according to one of the claims 26 to 34, wherein a contraction ratio (a / A1) of the by Inner edge of limited cross-section (a) to the flow cross-section (A1) of the measuring tube in a range between 1.3 and 3 is maintained. measuring system according to one of the claims 10 to 12 in conjunction with any one of claims 33 to 35, wherein a difference (A2 / A1-a / A1) between the aspect ratio (A2 / A1) and the contraction ratio (a / A1) greater than 0.2 is held. measuring system according to one of the claims 10 to 12 in conjunction with any one of claims 33 to 35, wherein a difference (A2 / A1-a / A1) between the aspect ratio (A2 / a1) and the contraction ratio (a / A1) less than 10 is kept. measuring system according to one of the claims 10 to 12 in conjunction with any one of claims 33 to 35, wherein a difference (A2 / A1-a / A1) between the aspect ratio (A2 / a1) and the contraction ratio (a / A1) greater than 0.25 and less than 8 is held. measuring system according to one of the preceding claims, the measuring tube a smaller caliber (D1) than an inlet side to the measuring system Connected inlet segment of the process line. measuring system according to claim 39, wherein the the feed segment of the process line facing inlet end of the flow conditioner has a caliber larger than a caliber (D1) of the measuring tube is, and that the measuring tube facing outlet end of the flow conditioner a caliber smaller than the caliber of the inlet end of the flow conditioner is. A measuring system according to claim 39 or 40, wherein the at least one inner edge projecting into the lumen of the flow conditioner is formed by the inner diameter of the inlet end (d). the flow conditioner is kept smaller than the caliber (D2) of the feed segment of the process line. measuring system according to one of the claims 39 to 41, with a caliber ratio (D2 / D1) of the caliber (D2) of the feed line of the process line to the caliber (D1) of the measuring tube greater than 1.1 is held. measuring system according to one of the claims 39 to 42, with a caliber ratio (D2 / D1) of the caliber (D2) of the feed line of the process line to the caliber (D1) of the measuring tube less than 5 is kept. measuring system according to one of the claims 39 to 43, with a caliber ratio (D2 / D1) of the caliber (D2) of the feed line of the process line to the caliber (D1) of the measuring tube is kept in a range between 1.2 and 3.1. measuring system according to one of the claims 39-44, wherein one of the at least one into the lumen of the flow conditioner projecting inner edge limited cross section of the lumen of flow conditioner a diameter (d) smaller than the caliber (D2) of the feed segment of the process line. measuring system according to one of the preceding claims, the measuring tube an installation length (L1) which is greater than an installation length (L2) of the flow conditioner is so that one Installation length ratio (L2 / L1) the installation length (L2) of the flow conditioner to the installation length (L1) of the measuring tube less than one is held. measuring system according to the previous claim in conjunction with one of claims 39 to 45, with a caliber ratio (D2 / D1) of the caliber (D2) of the feed line of the process line to the caliber (D1) of the measuring tube at least 10% of the installation length ratios (L2 / L1) of the installation length (L2) of the flow conditioner to the installation length (L1) of the measuring tube equivalent. measuring system according to one of the preceding claims, wherein the at least one immersed in the medium, especially during operation, Sensor element at a distance (Lm) from the inlet end of the measuring tube in and / or, esp. Immediately, is arranged on the measuring tube. measuring system according to the previous claim in conjunction with one of claims 39 to 47, wherein the at least one sensor element is placed so that a ratio of the Distance (Lm) to the caliber (D1) of the measuring tube is kept greater than one. measuring system according to one of the claims 18 to 49, with the baffle and the inner edge at least partially by an inlet side in the flow conditioner formed, in particular, extending to its inlet end, itself to the measuring tube rejuvenating Inner cone are formed. measuring system according to claim 50, wherein the forming the impact surface of the Strömungskonditionieres Inner cone has a flank angle (a), which is greater than 45 °, esp. greater than 60 °, is. measuring system according to claim 50 or 51, wherein the forming the impact surface of the Strömungskonditionieres Inner cone has a flank angle (a), which is smaller than 90 °, esp. Smaller as 88 °, is. measuring system according to one of the claims 50 to 52, where the baffle of the flow conditioner forming inner cone (a) has a flank angle which is greater than 60 ° and which is less than 88 °. measuring system according to one of the preceding claims, being in the flow conditioner an upstream from its baffle arranged, guiding from in the flow conditioner pouring Medium serving guide surface (L) is provided, which extends in the direction of the outlet end of flow conditioner extends. measuring system according to claim 54, wherein the, in particular conically formed, guide surface of the flow conditioner at least partially convex. measuring system according to claim 54 or 55, wherein the, in particular conical, baffle of the flow conditioner at least partially concave shaped. Measuring system according to one of claims 54 to 56, wherein the guide surface of the Strömungskonditionieres has a substantially S-shaped contour line. measuring system according to one of the claims 54 to 57, with the guide surface the flow conditioner itself to the measuring tube rejuvenating is trained. measuring system according to one of the claims 54 to 58, with the guide surface of the flow conditioner in is essentially conical in shape. measuring system according to one of the claims 1 to 53 in conjunction with any one of claims 54 to 59, wherein the at least one into the lumen of the flow conditioner protruding inside edge of a leading in the flow conditioner pouring Medium serving, in the direction of the outlet end of the flow conditioner extending guide surface (L) of the flow conditioner limited. measuring system according to one of the claims 1 to 53 in conjunction with any one of claims 54 to 60, wherein the guide surface and the inner edge at least partially by an inlet side molded in the flow conditioner, esp. to its outlet end towards extending, inner cone are formed. measuring system according to claim 61, wherein the forming the Leiffläche the Strömungskonditionieres Inner cone has a flank angle (β) that is larger than 2 °, esp. greater than 4 °, than is. measuring system according to claim 61 or 62, wherein the inner surface forming the Leiffläche the Strömungskonditionieres a flank angle (β) which is less than 45 °, esp. Less than 10 °, is. measuring system according to one of the claims 61 to 63, where the the guide surface of the flow conditioner forming inner cone has a flank angle (β), which is greater than 4 ° and the is less than 10 °. measuring system according to claim 50 and 61, wherein the baffle surface by an inlet side in the flow conditioner molded, extending in the direction of the inlet end first Inner cone and the guide surface through an inlet side in the flow conditioner molded, extending in the direction of the outlet end second Inner cone are formed. measuring system according to the preceding claim, wherein the baffle forming the first inner cone has a flank angle which is larger as a flank angle of the Leiffläche forming the second inner cone. Measuring system according to the preceding claim, wherein the first inner cone forming the baffle surface of the flow conditioner has a flank angle (a) which is greater than 45 °, in particular greater than 60 °, and which is less than 90 °, in particular less than 88 ° and wherein the second inner cone forming the guide surface of the flow conditioner has a flank angle ( 11 ) which is greater than 2 °, in particular greater than 4 °, and which is smaller than 45 °, esp. Less than 10 °. measuring system according to one of the preceding claims, wherein the at least one sensor element by means of at least one piezoelectric and / or by means of at least one piezoresistive Elements is formed. measuring system according to one of the preceding claims, wherein the at least one sensor element by means of at least one formed with an anchor corresponding plunger coil. measuring system according to one of the preceding claims, wherein the at least one sensor element by means of at least one in the measuring tube streaming Medium-touching, electrical potentials tapping measuring electrode is formed. measuring system according to one of the preceding claims, wherein the at least one sensor element by means of at least one on changes the measured variable responsive measuring capacitor is formed. measuring system according to one of the preceding claims, wherein the at least one sensor element by means of at least one electrical resistance is formed. measuring system according to one of the preceding claims, wherein the at least sensor element in operation under the action of in the measuring tube flowing Medium is repeatedly subjected to mechanical deformation. measuring system according to one of the preceding claims, wherein the at least sensor element in operation under the action of in the measuring tube flowing medium repeatedly moved relative to a static rest position. measuring system according to one of the preceding claims, the transducer at least one in the measuring tube arranged bluff body includes. measuring system according to the preceding claim, wherein the at least one, in particular at least proportionally in the measuring tube protruding, sensor element of the sensor assembly downstream of the at least one bluff body is arranged. measuring system according to one of the preceding claims, which is the transducer around a vortex flow sensor, esp. a vortex street Durchflußaufnehmer is. measuring system according to one of the claims 1 to 75, wherein the transducer is a magneto-inductive flow sensor is. measuring system according to one of the claims 1 to 75, wherein the transducer is a flow sensor vibration type, in particular a Corilolis mass flow sensor, a density sensor, and / or a viscosity sensor acts. measuring system according to one of the claims 1 to 75, wherein the transducer is an ultrasonic flow sensor is. Use of the measuring system according to one of the preceding claims for detecting at least one measured variable, in particular a mass flow, one Volume flow, a flow velocity, a density, a viscosity, a pressure, a temperature and / or the like, one in the Process line flowing medium. Method for detecting at least one measured quantity, in particular a mass flow rate, a volume flow rate, a flow rate, a density, a viscosity, a pressure, a temperature and / or the like, of a medium flowing in a process line by means of a measuring system inserted in the course of the process line, comprising a flow conditioner connected to a feed line of the process line and a transducer connected thereto, the method comprising the steps of: flowing the medium to be measured from the feed segment into the flow conditioner, damming medium flowing into the flow conditioner and inducing at least one substantially stationary one , esp. Also substantially stationary, toroidal vortex within flowing in the inlet region of the Strömungskonditionieres medium in such a way that a largest imaginary inertial main axis of the at least one toroidal vortex substantially coinciding with the imaginary longitudinal axis of the flow conditioner and / or an imaginary longitudinal axis of the measuring tube, - vorbeiströmlassen of medium to be measured on the at least one toroidal vortex and flow of medium to be measured from the flow conditioner in a measuring tube of the connected transducer, and Generating at least one measurement signal (s ₁ ) influenced by the measured variable to be detected, using at least one sensor element which reacts primarily to the measured variable, in particular also changes thereof ( 17 ). A method according to the preceding claim, wherein the Step of damming medium flowing into the flow conditioner further a step of inflating from medium to one that flows Medium in one, esp. Along a generatrix of the flow conditioner closed circumferential, opposing edge region of the flow conditioner baffle of the flow conditioner for inducing the at least one substantially stationary toroidal Vertebrae in the inlet area of the flow conditioner includes. The method of any one of claims 82 to 84, further comprising Steps of accelerating medium flowing in the flow conditioner in the direction of an imaginary longitudinal axis of the flow conditioner. The method of any one of claims 82 to 85, further comprising a step of inducing at least one further substantially stationary, in particular substantially stationary, toroidal vortex in the inlet region of the flow conditioner such that the largest imaginary main axis of inertia of each at least two toroidal vortex coincide substantially with one another. Method according to the preceding claim, wherein at least one of the steps of inducing substantially stationary toroidal Whirling in the inlet area of the flow conditioner Steps of passing by of medium at a projecting into a lumen of the Strömungsungskonditionieres, esp. Along one of its generatrices closed encircling, Inner edge of the flow conditioner includes.