EP3732388A1 - Tube for a transducer, transducer comprising such a tube, and measuring system formed therewith - Google Patents

Abstract

The tube is used to conduct a fluid flowing through the tube in a specified flow direction and for this purpose comprises a tube wall (110), which encloses a lumen (100*) of the tube, and an interference body (120), which is arranged within the tube but is nevertheless connected to the tube wall at an inner face of the tube wall facing the lumen. In the tube according to the invention, the tube wall has a maximum wall thickness (s_max) of more than 1 mm and at least two mutually spaced sub-segments (100-1, 100-2) with a respective wall thickness (s_110-1, s_110-2) that deviates from said maximum wall thickness (smax), wherein the sub-segment (100-1) is positioned upstream of the interference body (120) in the flow direction, and the sub-segment (100-2) is positioned downstream of the sub-segment (100-1) in the flow direction.

Description

 Pipe for a transducer, transducer with such a tube and thus formed

 measuring system

The invention relates to a suitable for a transducer tube and a transducer formed by means of such a tube for detecting a measured variable of a flowing fluid or a measuring system formed therewith for measuring a flow parameter of a fluid flowing in a pipe.

In the process measuring and automation technology are used for the measurement for measuring flow parameters, such as a flow velocity and / or a

Volumendurchflußrate of flowing fluids in piping, esp. Fast flowing and / or hot gases and / or fluid streams of high Reynolds number (Re), or with a respective flow velocity (u) corresponding volume or mass flow rates often as vortex flowmeters or trained as differential pressure flowmeters

Measuring systems used. Examples of such measuring systems are i.a. from JP-A 0682281, US-A 2017/0328750, WO-A 2008/061551, WO-A 2009/158605 or WO-A 2013/180843 are known and are among others. also offered by the applicant himself, for example under the trade name "DELTABAR PMD 55".

The measurement systems shown each have a detecting the pressure fluctuations in the flowing fluid, for example, to detect pressure fluctuations in a formed in the flowing fluid Kärmänschen vortex street, and / or detecting a pressure drop occurring in the flowing fluid useful transducer and thus electrically coupled measuring electronics which is adapted to receive and process sensor signals generated by the transducer, in particular the at least one

To generate flow parameters representing measured values. Namely transducer is in turn by means of a in the course of each - used, for example, as a system component of a heat supply network or a turbine - used pipe, leading a flowing with a given flow direction fluid useful - for example, monolithic or composed of individual parts - tube. The tube has a metallic tube wall, a lumen enclosed therefrom, and a metallic disruptive body arranged at least partially in the lumen of the tube-for example also connected to an inner side of the tube wall facing the lumen-and thus circulated during operation of fluid. In the case of the measuring transducer shown in JP-A 0682281 or the measuring system formed therewith, the disturbing body is designed, for example, as a bluff body formed in a prismatic manner, or the bluff body is in each case arranged to be in it By-passing fluid to induce vortex with a fluid rate dependent on the flow velocity (1 / fv _tx ) such that a Kärmän vortex street is formed in the fluid flowing downstream of the obstruction body. Alternatively, the bluff body, as in, inter alia, in US-A 2017/0328750, WO-A 2008/061551, the

WO-A 2009/158605 or WO-A 2013/180843, for example, also be adapted to increase a flow velocity of a fluid flowing past and / or through a static pressure prevailing in a fluid flowing past and / or through reduce and / or provoke a dependent of a volumetric flow pressure difference along a measuring path formed by the first and second sub-segments of the pipe wall, or as a diaphragm, esp. Namely as a standard diaphragm, be formed. in the

Result, each of the tubes accordingly each one - usually circular

formed - maximum first flow cross-section and in at least one adjoining the bluff body, for example, formed between the bluff body and the pipe wall and / or within the Störrkörpers, a deviating from namely maximum flow cross-section second flow cross-section. Like u.a. also in the mentioned

WO-A 2009/158605 shown, the tube may also in a upstream flow direction upstream of the bluff body, immediately downstream of the aforementioned first flow cross-section area both from namely namely first flow cross-section and from the aforementioned second flow cross-section, for example, namely greater than the second flow cross-section of the tube formed, circular third

Have flow cross-section. Moreover, in a region located downstream of the bluff body in the flow direction, the tube may have a fourth flow cross section deviating from the aforementioned first flow cross section and from the aforementioned second flow cross section, for example larger than the second flow cross section of the tube. The two third and fourth flow cross sections may, for example, also the same size and / or substantially by a substantially circular cylindrical first region of the lumen enclosing, substantially hollow cylindrical first sub-segment of the tube or by a substantially circular cylindrical second region of the lumen enclosing, substantially be formed hollow cylindrical second sub-segment tube. The aforementioned first flow cross section of the tube, in turn, can accordingly be formed by a third subsegment of the tube enclosing a conical third region of the lumen and / or forming a concentric reduction in the flow direction.

For the purpose of generating the sensor signals, each of the above-described transducers comprises at least two sensor elements - typically of identical construction - of which a first one

Sensor element in a region located upstream of the bluff body and a second

Sensor element is positioned in a region located downstream of the obstruction body. At least in the case of the transducer shown in JP-A 0682281, the second sensor element described above serves to detect pressure fluctuations in the Kärmän vortex street formed in the flowing fluid and to convert it into a sensor signal representing the pressure fluctuations, namely to provide an electrical signal, which is provided here a pressure prevailing within the fluid, due to opposing vortex downstream of the bluff body periodic fluctuations corresponding pressure corresponds or which has a corresponding to the rate of detachment of the vortex signal frequency (~ fv _tx ).

In the case of the transducer shown in JP-A 0682281 or in WO-A 2009/158605, openings in the pipe wall are provided for the purpose of connecting the sensor elements to the pipe or the coupling to the fluid guided therein, through which one is in each case transferred led by pressure serving pressure line or to each of which such a pressure line is connected. A disadvantage of the use of such pressure line u.a. in that due to the openings in the pipe wall additional measures are required, that the pipe together with the

Secure pressure lines again and seal off leakage. Another disadvantage is also to be seen in the fact that such pressure lines themselves influence the measurement or can be the cause of measurement errors.

Taking this into account, it is an object of the invention to provide a suitable for a transducer of the aforementioned type tube to which the required for the measurement at least two sensor elements can be coupled without waiving openings in the pipe wall.

In order to achieve the object, the invention consists in a tube for guiding a fluid flowing with a predetermined flow direction, comprising: a tube wall enclosing a lumen of the tube, for example metallic and / or monolithic, and a tube wall arranged inside the tube, yet at a lumen facing Inside the pipe wall associated with, for example, metallic and / or monolithic, bluff body.

The tube wall of the tube according to the invention has a more than 1 mm, for example more than 2 mm, amounting maximum wall thickness and at least two spaced-apart, for example, equal and / or gleichgeformte, sub-segments with one of the maximum wall thickness, for example, more than 30% more similar maximum wall thickness and / or by more than 1 mm, deviating, for example, less than 1 mm and / or more than 0.1 mm amount, wall thickness, wherein a first sub-segment in the flow direction upstream of the obstruction body and a second sub-segment at least partially in

Flow direction downstream of the first subsegment, for example, namely at least partially in the region of the bluff body and / or at least partially in the flow direction

downstream of the bluff body, is positioned. Moreover, the invention consists in a formed by such a tube, the detection of at least one measured variable of a flowing fluid useful transducer, which also fixed to the first sub-segment of the tube wall and / or in the vicinity, for example

piezoelectric or capacitive or optical, first sensor element, which is adapted to detect elastic deformation of the same subsegment and in one with the same

Deformations corresponding first sensor signal, for example, with a dependent of the same deformation of electrical voltage and / or dependent of nämlicher deformation electric current to convert, and fixed to the second sub-segment of the pipe wall and / or in the vicinity, for example, piezoelectric or capacitive or optical and or to the first sensor element of identical, second sensor element, which is adapted to detect elastic deformations nämlichen subsegment and in one with the same

Deformations corresponding second sensor signal, for example, with a dependent of nämlicher deformation electrical voltage and / or a dependent of the same deformation electrical current to convert includes.

Furthermore, the invention also consists in a formed by means of such a transducer

Measuring system for measuring at least one, for example temporally variable,

Flow parameter, for example, a flow rate and / or a volumetric flow rate, of a fluid flowing in a pipeline, which measuring system also a measuring electronics, which is adapted to receive and process both the first sensor signal and the second sensor signal, for example the generating measured values representing at least one flow parameter.

According to a first embodiment of the invention it is further provided that the tube has a, for example, more than 20 mm ² amount and / or circular formed, maximum first flow cross-section. This refinement further provides for the tube to have, in at least one region adjoining the disruptive body, for example formed between the obstruction body and the tube wall, a second flow cross-section deviating in size and / or shape from the maximum flow cross-section. Moreover, the tube may be in a flow upstream of the

Bluff body, equally well located downstream of the first flow cross-section area of both the first flow cross-section and the second flow cross-section

deviating, for example, circular and / or larger than the second flow cross-section of the tube formed, have third flow cross-section, and the tube can be located in a downstream flow direction downstream of the obstructed area one of the first Having flow cross-section as well as the second flow cross-section deviating, for example, the third flow cross-section same and / or circular and / or greater than the second flow cross-section of the tube formed fourth flow cross-section.

According to a second embodiment of the invention it is further provided that the tube in

Flow direction upstream of the bluff body has a cylindrical, for example, circular cylindrical, the first area of the lumen enclosing, for example, hollow cylindrical, first sub-segment and wherein the tube in the flow direction downstream of the

Bluff body has a cylindrical, for example, circular cylindrical, second region of the lumen enclosing, for example, hollow cylindrical, second sub-segment. These

Further development is further provided that the tube in the flow direction

upstream of the first sub-segment has a one, for example, in the flow direction concentric reduction forming, conical third region of the lumen enclosing, for example, the first flow cross-section forming, third sub-segment. Furthermore, in the flow direction downstream of the second sub-segment, the tube can also have a fourth sub-segment with a flow cross-section deviating from the flow cross-section of the second subsegment.

According to a third embodiment of the invention it is further provided that the first sub-segment of the pipe wall is circular and / or flat on an outer side facing away from the lumen.

According to a fourth embodiment of the invention it is further provided that the second sub-segment of the pipe wall is circular and / or flat on an outer side facing away from the lumen.

According to a fifth embodiment of the invention it is further provided that the first and second sub-segments of the tube wall are the same size and / or gleichgeformt, for example, identical, are.

According to a sixth embodiment of the invention, it is further provided that the pipe wall and obstructing bodies are components of one and the same monolithic molded part.

According to a seventh embodiment of the invention, it is further provided that the pipe wall and obstruction body consist of the same material.

According to an eighth embodiment of the invention is further provided that the inside of the pipe wall has no welds. According to a ninth embodiment of the invention, it is further provided that the pipe wall is free of joints.

According to a tenth embodiment of the invention is further provided that the tube wall has no openings or openings.

According to an eleventh embodiment of the invention it is further provided that the inside of the tube wall has no projections.

According to a twelfth embodiment of the invention, it is further provided that the inside of the tube wall is smooth at least in the region of the subsegments.

According to a thirteenth embodiment of the invention, it is further provided that the bluff body is adapted to increase a flow velocity of a passing and / or passing fluid and / or to reduce and / or along a static pressure prevailing in a fluid passing and / or flowing therethrough to provoke a formed by the first and second sub-segments of the pipe wall measuring a dependent of a volumetric flow pressure difference.

According to a fourteenth embodiment of the invention it is further provided that the bluff body is adapted to induce vortex in the fluid flowing past it, for example, such that in the downstream of the bluff body and / or along one of the first and second

Partial segments of the pipe wall formed measuring path flowing fluid a Kärmänsche

Vortex street is formed.

According to a fifteenth embodiment of the invention it is further provided that the bluff body is formed as a prismatically shaped bluff body.

According to a sixteenth embodiment of the invention it is further provided that the bluff body is formed as a diaphragm, for example as a standard diaphragm.

According to a seventeenth aspect of the invention, it is further contemplated that the tube is made by a metal injection molding (MIM) process.

According to a development of the invention, the tube further comprises an inlet side in the flow direction first pipe end receiving first connecting flange and a in

Flow direction outlet side second pipe end second flange. The Pipe wall and the first and second connecting flanges can for example also be components of the same monolithic molded part.

A basic idea of the invention is to avoid undesired openings or breakthroughs in the tube wall of a tube suitable for a transducer of the type in question by providing two subsegments each serving as a sensor pocket in the tube wall, each for receiving at least one sensor element are suitable, wherein the wall thickness of each of the aforementioned subsegments can be readily chosen so that on the one hand in operation for the generation or processing of sensor elements generated by the sensor signals sufficient deformation is made possible and on the other hand a sufficient for the operation pressure resistance of the tube is guaranteed ,

The invention and advantageous embodiments thereof are described below with reference to

Embodiments explained in more detail, which are illustrated in the figures of the drawing. The same or equivalent or similar acting parts are the same in all figures

Provided with reference numerals; if it is useful for clarity or otherwise makes sense, is omitted reference numerals already mentioned in subsequent figures. Further advantageous embodiments or developments, esp. Combinations initially only individually explained aspects of the invention will become apparent from the figures of the drawing and / or from the claims themselves.

In detail show:

Fig. 1 in a side view by means of a transducer and a thereto

 connected measuring electronics formed measuring system for measuring a

 Measured variable of a fluid flowing in a pipeline;

FIG. 2 shows a top view of a measuring transducer suitable for a measuring system according to FIG. 1; FIG.

3A, 3B in a sectional side view and in a front view of a variant of a suitable for a measuring system of Figure 1 transducer ..; and

4A, 4B in a sectional side view and in a front view of a further variant of a suitable for a measuring system according to FIG. 1 transducer. In FIGS. 1, 2, 3A, 3B, 4A and 4B, exemplary embodiments of a measuring system for measuring at least one possibly time-variable measured variable, in particular a flow parameter such as a flow velocity v and / or a volumetric flow rate V ', one in a conduit of flowing fluid shown. The pipeline can, for example, as

Plant component of a bottling plant, a heat supply network or a

Turbine circuit formed, therefore, the fluid may for example be an aqueous liquid, steam or, for example, a discharged from a steam line condensate. However, fluid can also be, for example, a (compressed) natural gas or a biogas, and consequently the pipeline can also be, for example, a component of a natural gas or biogas plant or a gas supply network.

For detecting the at least one measured variable, the measuring system has a transducer 10, which is provided or designed to be flowed through by fluid in a flow direction during operation and temporally changing pressures in the flowing fluid and / or a pressure drop occurring in the flowing fluid and / or or to detect pressure fluctuations in the flowing fluid, for example in a Kärmän vortex street formed therein, and in two with it

corresponding, for example electrical or optical, sensor signals s1, s2 to convert. In addition, the measuring system has a measuring electronics 20 which is adapted to receive and process both the aforementioned sensor signals, for example to generate measured values XM ZU representing the at least one flow parameter. As can be seen from Fig. 1, the measuring system further includes a - housed for example in a pressure and / or shock-resistant protective housing 200 - measuring electronics 20 which are connected to the

Measuring transducer 10 is electrically connected or in the operation of the measuring system with the

Transducer 1 communicates. In particular, the measuring electronics 20 are set up to receive and process the sensor signals s1, s2, for example to generate the measured values XM ZU representing the at least measured variable. The measured values XM can, for example, be visualized on site and / or-wired or according to DIN IEC 60381-1 compliant via a connected fieldbus and / or wirelessly by radio or IEEE 802.15.1 or IEEE 802.15.4 compliant-to an electronic data processing system, such as a Programmable logic controller (PLC) and / or a process control station to be transmitted. The protective housing 200 for the

Measuring electronics 20 may be made of, for example, a metal, such as a stainless steel or aluminum, and / or by means of a casting process, such as casting. a precision casting or a

Die casting process (HPDC), to be manufactured; but it may also be formed, for example, by means of a plastic molding produced by injection molding. The measuring system, as also shown in Fig. 1, for example, be designed as a measuring system in a compact design, in which the protective housing 200 together with the arranged therein

Measuring electronics 20 positioned directly on the transducer 10 and - for example by means of a neck-shaped connecting piece 300 - with the transducer 10 is rigid, possibly also releasably connected.

For guiding the flowing fluid, the measuring transducer, as also shown in FIGS. 3A and 3B or 4A and 4B respectively, or readily apparent from a combination of the figures, comprises a tube 100 having a lumen 100 ^{* of} the tube, for example metallic and / or monolithic - pipe wall 1 10 and one within the tube 100 and its lumen 100 arranged, however, at one of the lumen 100 facing the inside of the tube wall 1 10 associated therewith - for example, metallic and / or

monolithic bluff body 120. The same bluff body 120 may, for example, be designed or arranged to increase a flow velocity of the fluid flowing past and / or through a fluid flowing in and / or through it

reduce prevailing static pressure, for example, so that thereby in

Flow direction is provoked by a volume flow dependent pressure difference. Alternatively or in addition, the bluff body may also be set up to be in it

to induce vortex fluid, for example, such that in the downstream of the bluff body flowing fluid Kärmänsche vortex street is formed. Pipe wall and bluff body can advantageously, for example, from the same material, for example, one, possibly also stainless steel or a nickel-based alloy exist. According to a further embodiment of the invention, the pipe wall and disruptive bodies are constituents of one and the same monolithic molded part. As a result, the pipe wall can advantageously be kept free of joints, which are usually expensive to produce and / or to be tested, or actually unwanted or annoying welds on the inside of the pipe wall can be avoided. According to a further embodiment of the invention, the tube is for a through

Metal injection molding (MIM) produced. At the

Metal powder injection molding is first of a fine metal powder and a likewise powdered plastic a pasty, yet sprayable mass with a metal powder content of typically more than 90 wt.% (Weight percent) prepared by means of

one - for example, also for conventional plastic injection molding

suitable - processed injection molding machine to form the tube to be molded. Moreover, in the metal powder injection molding process, this molding is deprived of the plastic while retaining its shape, and the metal remaining in the molding is finally sintered. By for the production of the tube such

Metal powder injection molding is applied, the tube wall 1 10, not least also their sub-segments 1 10-1, 1 10-2, are made very precisely, possibly even while avoiding otherwise very complicated post-processing of the tube 100 and its surfaces. The pipe 100, as also indicated in FIGS. 3A and 3B respectively, is readily apparent from a combination of FIGS. 3A, 3B, 4A and 4B, according to a further embodiment of the invention further comprising, for example, more than 20 mm ² and / or circular

trained - first flow area Ai, the same time a maximum

Flow cross-section of the tube 100 corresponds to (A1 - A _max ), on. In the case of a lumen 100 having only a circular flow cross-section, a diameter of the flow cross-section Ai that is more than 5 mm, for example, also corresponds to a maximum diameter of the lumen 100 ^* . For the purpose of incorporating the tube or the transducer thus formed, the tube 100 according to a further embodiment of the invention, an inlet side in the flow direction first pipe end 10+ first

Connection flange 130 and a second outlet end in the flow direction second tube end 10 # second connecting flange 140 have. Pipe wall 1 10 and flanges 130, 140 may, as also in Fig. 1, 3A and 4A respectively indicated, also, for example, components one and the same, for example, the bluff body 120 with comprehensive, monolithic molding.

The tube 100 can also be designed, for example, such that in the flow direction upstream of the bluff body 120 there is a cylindrical, possibly also - as in FIGS. 3A and 3B or 4A and 4B respectively indicated - circular-cylindrical first region of the lumen

enclosing, for example, hollow cylindrical, first sub-segment 100-1 and in

Flow direction downstream of the bluff body 120 has a cylindrical, possibly also circular cylindrical, second region of the lumen enclosing, for example, hollow cylindrical, second sub-segment 100-2. According to a further embodiment of the invention it is further provided that the tube 100 in addition to the aforementioned sub-segments 100-1, 100-2 in the flow direction upstream of the aforementioned subsegment 100-1 a one,

For example, in the flow direction has a concentric reduction forming, conical third region of the lumen enclosing, possibly also the flow cross section Ai forming third subsegment 100-3. Further, the tube 100 in the flow direction downstream of the aforementioned subsegment 100-2 a, for example, a diffuser or in

Flow direction forming a widening or even a throttle or in

Direction of flow forming a reduction, fourth sub-segment 100-4 with a from the

Flow cross-section of the sub-segment 100-2 deviating, for example, compared to namely flow cross-section of the subsegment 100-2 enlarged or reduced,

Have flow cross-section.

According to a further embodiment of the invention, the tube 100, as also indicated in FIGS. 3A and 3B respectively, can be seen in at least one of them adjacent to the bluff body 120, for example also between bluff body 120 and tube wall 110 formed region with respect to size and / or shape of vorbezeichnetem maximum flow cross-section Ai deviating second flow cross-section A ₂ . In addition, the pipe 100 may be in a flow direction upstream of the bluff body 120, but downstream located downstream of the flow cross-section Ai an area designated in terms of size and / or shape of both Weil namely flow cross-section Ai and

Flow cross section A ₂ deviating - for example, larger than the same

Flow cross-section A ₂ formed - third flow area A3 and in an in

Flow direction located downstream of the bluff body 120 also one in terms of size and / or shape of both the flow area Ai and from

Flow cross-section A ₂ deviating - for example, the aforementioned

Have flow cross section A ₃ same and / or greater than the flow cross-section A ₂ formed fourth flow cross-section A4. The flow cross-section A3 and / or the

Flow cross-section A4 can for example also be circular. In addition, the flow cross-section A3 may be formed by the aforementioned sub-segment 100-1 of the tube 100 and the flow cross-section A4 by the aforementioned sub-segment 100-2 of the tube 100.

In the pipe 100 according to the invention, the pipe wall 1 10 a more than 1 mm amounts, for example, circumferentially or along an imaginary circumferential line constant, maximum

Wall thickness s _max and at least two, esp. In the flow direction, spaced from each other, for example, equally sized and / or gleichgeformte, sub-segments (1 10-1, 1 10-2) each having one of the aforementioned maximum wall thickness s _max deviating (namely in comparison smaller than this) wall thickness s-110-1 or s-110-2, of which two sub-segments, as also shown in FIGS. 3A and 4A respectively, a first sub-segment 1 10-1 in the flow direction

upstream of the bluff body 120 and a second sub-segment 1 10-2 in the flow direction downstream of the subsegment 1 10-1 - for example, at least partially in the region of the bluff body 120, possibly also partially in the flow direction downstream of the

Bluff 120 is positioned. The two sub-segments 1 10-1, 1 10-2 are in particular provided to receive respectively at least one of the generation of one of the aforementioned sensor signals useful sensor element or to form corresponding sensor pockets of the tube. Advantageously, the sub-segments 1 10-1, 1 10-2 of the tube wall 1 10 are accordingly equal in size and / or gleichgeformt, for example, identical in construction, and / or circular. Alternatively or in addition, the sub-segment 100-1 and / or the sub-segment 100-2 can be formed flat on a respective outer side facing away from the lumen, for example to allow the respective sensor element to be coupled as simply as possible to the respective sub-segment. As a result, the tube wall may advantageously also be designed, for example, such that it has no apertures or openings and / or that it has no projections or is smooth, at least in the region of the partial segments 1 10-1, 1 10-2. According to a further embodiment of the invention, the means 100 formed by the tube

Accordingly, a transducer at the sub-segment 1 10-1 or in its vicinity, for example cohesively or adhesively, fixed first sensor element 210 which is adapted to detect elastic deformations nämlichen subsegment and in one with the same

Deformations corresponding first sensor signal, for example, namely with a dependent of nämlicher deformation electrical voltage and / or one of the same

Deformation dependent electric current, to convert. In addition, the transducer further comprises a partial segment 1 10-2 or in its vicinity, for example cohesively or adhesively, fixed, for example, to the sensor element 210 identical, second sensor element 220, which is adapted to detect elastic deformations nämlichen subsegment and in a corresponding with the same deformations second sensor signal, for example, with a dependent of nämlicher deformation electrical voltage and / or one of the same

Deformation dependent electric current, to convert. Each of the sensor elements 210, 220 may be designed, for example, in each case as a piezoelectric, capacitive or even optical sensor element. The wall thickness sno-i, sno-2 of the aforementioned subsegments 1 10-1, 1 10-2 is advantageously selected in each case such that a sufficient for the generation or processing of the sensor signals s1, s2 deformation allows, while sufficient

Compressive strength of the tube is ensured, and may for example be less than 1 mm and / or more than 0.1 mm and / or, for example, each also be chosen so that they are of the maximum wall thickness by more than 1 mm and / or more than 30% of the maximum

Wall thickness deviates. The vorbe vorbezeichnet maximum wall thickness, in turn, for example, more than 2 mm, for example, be more than 5 mm. According to a further embodiment of the invention is further provided that each of the sub-segments 1 10-1, 1 10-2 on the lumen 100 ^* each side facing away from each one has a largest diameter which is not greater than a maximum diameter of the aforementioned flow cross-section Ai and / or less than 20 mm.

According to a further embodiment of the invention, the bluff body is adapted to induce vortex in the fluid thereto, such that in the downstream of the bluff body 120 and / or along a by means of the sub-segments 1 10-1, 1 10-2 the tube wall 1 10 formed test section flowing fluid is formed a Karmane vortex street, and / or is the bluff body 120, as also indicated in FIGS. 3A and 3B or seen from their synopsis, as a prismatically shaped bluff body. The Teilsegemente 1 10-1, 1 10-2 the

Pipe wall 1 10 and the bluff body 120 are in this case in particular dimensioned and arranged so that the Teilsegement 1 10-2 in such an area adjacent to the lumen 100 ^{* of} the tube 100 and contacted the guided therein fluid, which in the operation of - for example when

Swirl Durchflußmeßgrät trained - measuring system is taken regularly by the aforementioned Karman vortex street, so that the means of the sensor element 220th detected pressure fluctuations caused by periodic pressure fluctuations caused by the swirl body 120 with a rate of detachment (~ 1 / fv _tx ) and the sensor signal s2 having a signal frequency corresponding to the rate of detachment nämlicher (~ fv _tx ). The

Accordingly, measurement electronics 20 can also be set up for this, based on the signal frequency of the sensor signal s2, possibly also - as shown in the aforementioned JP-A 0682281 - taking into account also the sensor signal s1 measured values for the at least one measured variable to be detected, for example, the flow velocity and / or the

Volume flow rate to determine. According to another embodiment of the invention, the bluff body 120 is provided or set up to provoke along a measuring section formed by the aforementioned sub-segments 100-1, 100-2 of the pipe wall 1 10 a dependent of a volumetric flow pressure difference, and / or is the bluff body , as also shown schematically in FIGS. 4A and 4B or also apparent from their combination, as a diaphragm, for example as a standard diaphragm. In this case, the measuring electronics 20 can also be set up to determine, based on the sensor signals s1, s2, the aforementioned pressure difference and, derived therefrom, measured values for the at least one measured variable to be detected.

Claims

PATENT APPLICATIONS

A pipe for guiding a fluid flowing in a predetermined flow direction, comprising:

a metallic and / or monolithic one enclosing a lumen (100 ^* ) of the tube, esp.

 Pipe wall (1 10);

- And one inside the tube arranged, however, at one of the lumen (100 ^* )

 facing inside of the pipe wall associated therewith, esp. Metallic and / or monolithic, Störkörper (120);

- Wherein the pipe wall (1 10) amounts to more than 1 mm, esp. More than 2 mm, maximum

Wall thickness (s _max ) has;

- And wherein the tube wall (1 10) at least two spaced apart, esp. Equal sized and / or gleichgeformte, sub-segments (1 10-1, 1 10-2), each with one of the maximum wall thickness, esp. By more than 30% more similar maximum wall thicknesses and / or more than 1 mm, deviating, in particular less than 1 mm and / or more than 0.1 mm,

 Wall thickness (sno-i, S110-2), of which two sub-segments (1 10-1, 1 10-2) a first sub-segment (1 10-1) in the flow direction upstream of the bluff body (120) and a second sub-segment (1 10-2) at least partially in the flow direction downstream of the first

 Partial segment (1 10-1), esp. At least partially in the region of the bluff body (120) and / or at least partially in the flow direction downstream of the bluff body (120) is positioned.

2. Pipe according to one of the preceding claims, wherein the tube has a, in particular more than 20 mm ² amount and / or circular design, maximum first flow cross-section (Ai);

3. Pipe according to the preceding claim, wherein the tube in at least one of the

Bluff body (120) bordering, esp. Namely between the bluff body and the pipe wall formed region having a respect to size and / or shape of namely maximum flow cross section deviating second flow cross-section (A ₂ ).

4. Pipe according to the previous claim,

 - wherein the tube in a flow direction upstream of the bluff body (120), just next to the downstream of the first flow cross-section (Ai) located area in terms of size and / or shape of both the first flow area (Ai) and the second

Flow cross section (A ₂ ) deviating, esp. Circular and / or greater than the second flow cross-section of the tube formed, third flow cross-section (A3);

- and wherein the tube in a downstream flow direction of the bluff body (120)

 localized area in terms of size and / or shape both from the first

 Having flow cross-section as well as the second flow cross-section deviating, esp. The third flow cross-section same and / or circular and / or greater than the second flow cross section of the tube formed, fourth flow cross-section (A4).

5. Pipe according to one of the preceding claims, wherein the tube in the flow direction

upstream of the bluff body (120) has a cylindrical, insb. circular cylindrical, the first area of the lumen enclosing, esp. Hollow cylindrical, first subsegment (100-1) and wherein the tube in the flow direction downstream of the obstruction body a cylindrical, esp. circular cylindrical, second Has area of the lumen enclosing, esp. Hollow cylindrical, second sub-segment (100-2).

6. Pipe according to claim 4 and 5,

- Wherein the first sub-segment (100-1) forms the third flow cross-section (A ₃ );

 - And wherein the second sub-segment (100-2) forms the fourth flow cross-section (A4).

7. Pipe according to one of claims 5 to 6, wherein the tube in the flow direction upstream of the first sub-segment (100-1) a one, esp., In the flow direction forming a concentric reduction, conical third region of the lumen enclosing, esp. The first flow cross-section having forming, third subsegment (100-3).

8. Pipe according to claim 7, wherein the tube (100) in the flow direction downstream of the second subsegment (100-2) has a fourth subsegment (100-4) with a flow cross section of the second subsegment (100-2) deviating flow cross section.

9. Pipe according to one of the preceding claims,

 - Wherein the first sub-segment of the pipe wall on a side facing away from the lumen is circular and / or planar; and or

- Wherein the second sub-segment of the tube wall on a side facing away from the lumen is circular and / or planar; and or - Wherein the first and second sub-segments of the pipe wall are the same size and / or gleichgeformt, esp. Namely identical.

10. Pipe according to one of the preceding claims,

 - wherein the pipe wall and obstruction are components of one and the same monolithic molding; and or

 - Where pipe wall and bluff body made of the same material.

1 1. Pipe according to one of the preceding claims,

 - wherein the inside of the pipe wall has no welds; and or

 - The pipe wall is free of joints; and or

 - wherein the inside of the tube wall has no projections; and or

 - Wherein the inside of the tube wall is smooth at least in the region of the sub-segments; and or

- The pipe wall has no openings or openings.

12. Pipe according to one of the preceding claims, further comprising:

 - One in the flow direction inlet side first pipe end (100+) summarizing first

 Connecting flange (130);

 - And one in the flow direction outlet side second pipe end (100 #) holding the second connecting flange (140).

13. Pipe according to the preceding claim, wherein the pipe wall and the first and second

Flanges are components of the same monolithic molding.

14. Pipe according to one of the preceding claims, wherein the bluff body is arranged, a

To increase flow velocity of a flowing past and / or flowing fluid and / or a prevailing in a passing and / or flowing fluid static pressure and / or along a measuring section formed by the first and second sub-segments of the tube wall a dependent of a volume flow pressure difference to provoke.

15. Pipe according to one of the preceding claims, wherein the bluff body is adapted to induce vortex in the fluid thereto, esp. Such that in the downstream of the

Bluff body and / or along a formed by means of the first and second sub-segments of the pipe wall measuring path fluid forming a Karman vortex street is formed.

16. Pipe according to one of the preceding claims, wherein the bluff body is formed as a prismatic shaped bluff body.

17. Pipe according to one of claims 1 to 15, wherein the disruptive body as a diaphragm, esp. Namely as a standard diaphragm, is formed.

18. Pipe according to one of the preceding claims, produced by a

Metal injection molding (MIM).

19. A transducer for detecting at least one measured variable of a flowing fluid, which

Measuring transducer comprises:

- A tube (100) according to one of the preceding claims;

- A fixed to the first sub-segment of the pipe wall and / or in the vicinity, esp.

 piezoelectric or capacitive or optical, first sensor element (210), which is adapted to detect elastic deformations of the same subsegment and in a corresponding with the same deformations first sensor signal, esp. With a deformation of the same dependent electrical voltage and / or one of nämlicher deformation dependent electric current, to convert;

- And a fixed to the second sub-segment of the pipe wall and / or in the vicinity, esp.

 piezoelectric or capacitive or optical and / or to the first sensor element of identical, second sensor element (220) which is adapted to detect elastic deformations nämlichen subsegment and in a same deformations with the same second sensor signal, esp. With a dependent of the same deformation electrical

 Voltage and / or a dependent on the same deformation electrical current to convert.

20. Measuring system for measuring at least one, in particular temporally variable,

 Flow parameter, in particular a flow rate and / or a volume flow rate, of a fluid flowing in a pipeline, the measuring system comprising:

 - For detecting pressure fluctuations in the flowing fluid, esp. Namely for detecting pressure fluctuations in a formed in the flowing fluid Kärmänschen vortex street, and / or for detecting a pressure drop occurring in the flowing fluid one

 A transducer (10) according to claim 19;

 - And a measuring electronics (20), which is adapted to both the first sensor signal and the second sensor signal to receive and process, esp. Namely generate the at least one flow parameter representative measured values (XM) ZU.