WO2008061551A1 - Method for the diagnosis of a blockage of a pulse transfer in a pressure transducer, and a pressure transducer - Google Patents

Abstract

The invention discloses a method for the operation of a pressure transducer (40) and such a pressure transducer (40), which is connected by means of at least one high pressure pulse transfer and low pressure pulse transfer (16, 18) to a line (12) in the region upstream of and downstream of a point of discontinuity, particularly to a baffle (14), wherein a pressure sensor (20) comprised in the pressure transducer (40) supplies a measurement signal (22) with regard to a pressure in the high pressure or low pressure pulse transfer (16, 18), or a difference thereof, wherein the measurement signal (22) supplied by the pressure sensor (20) is influenced by an accumulating body (34) provided in the region of the baffle (14), and the measurement signal (22) is analyzed, at least with regard to a contribution to the measurement signal (22), by means of the accumulating body.

Description

description

Method for diagnosing a blockage of a pulse line in a pressure transmitter and pressure transmitter

The invention relates to a method for the diagnosis of a Ver ^¬ stuffing of a pulse line in a (pressure) transducer and a (pressure) transducer, which is prepared for the execution of the method and provided. Transmitters of the above type are known per se and in particular for measuring pressure changes at a discontinuity, z. B. a so-called orifice, provided in a liquid or a gas (fluid) flowed through line. Such pressure changes are detected via pressure differences arising at the metering orifice. On the basis of such a differential pressure measurement and a flow measurement is possible.

The pressure transmitter comprises a (differential) pressure sensor, which is coupled via so-called impulse or differential pressure lines to an area before and after the point of discontinuity as a sensorically effective element. However, such a coupling may diminish over time, e.g. For example, by clogging one or both impulse lines (clogging, fouling). However, a decreasing coupling can be detected under certain circumstances on measurement signals recorded by the pressure sensor. As far as the invention so a method and a corresponding device for the diagnosis of a pulse line - ie in particular a detection of clogging of one or more impulse lines and / or detection of deposits on the orifice or acting as an interface between the impulse lines and the pressure transducer membrane and / or In particular, it relates to a method and a corresponding device for analyzing a characteristic value with regard to a deviation from or a correspondence with at least one predetermined or predefinable reference value. A declining or disturbed coupling is so far z. B. recognizable by a measure of the conformity of the characteristic value with such a reference value or a plurality of such reference values.

Generic methods or devices are well known. From US 5,680,109 z. For example, it is known to use an additional absolute pressure sensor in addition to a differential pressure transducer and to compare a variance of the measurement noise with a reference value. In WO 2001 35174 it is proposed to determine an independent reference signal whose difference from the measurement signal permits statements about a deterioration in the quality of the measurement signal. To evaluate the measurement signal, it has become known from US Pat. No. 6,532,392 to compare the measurement signal with a predetermined value of a parameter and to use predetermined rules, fuzzy logic or neural networks for the final evaluation. From WO 97 36215 it is known to determine a statistical parameter of a digitized measurement signal by means of predetermined rules, fuzzy logic or neural networks and then to apply a fuzzy membership function to the statistical parameter. It is further known from US Pat. No. 6,654,697 to determine a difference between a digitized measurement signal and the ascertained mean value by means of a moving-average algorithm. From this difference, diagnostic data are then determined taking into account current and historical data, wherein in a training mode from the current and historical data, a trained record is calculated. From US 6,539,267 is finally known, by means of an algorithm 'a statistical parameters, such. Variance or rate of change, and to generate a trained value by a microprocessor by monitoring the statistical parameter during normal operation. For different framework conditions, the trained parameter can be adapted dynamically.

Further prior art results from the following documents: WO 97 48974; JP 2004 354280; US 6,397,411; US 2002 029,130; US 2004 068,392; US 2004 204,883; US 6,701,274; US 5,570,300; US 5,675,724; US 5,665,899; US 5,661,668; US 6,047,220; US 5,956,663; US 5,828,567 and US 5,495,769.

In addition, in the unpublished DE 10 2005 023 115 an approach for the simultaneous detection of back pressure and eddy frequency by direct measurement of the forces acting on a bluff body to be treated, as in R. Müller: "Self-monitoring differential pressure-based flow measurement for liquids", dissertation, TU Darmstadt, submitted on September 15, 2005. However, the continuous use of the vortex sensor and the consideration of higher-frequency components of the resulting signals increase the computational effort.

An object of the invention is to improve the detection of blockages and the like of the pulse pressure lines or in the area of the pulse pressure lines.

This object is achieved with the features of claim 1. For this purpose, in a method for operating a pressure transducer, which is connected at least to a high pressure and a low pressure pulse line to a line in an area before and after a point of discontinuity, in particular a (measurement) aperture, wherein a pressure sensor encompassed by the pressure transducer is a measurement signal provided with respect to a pressure in the high or low pressure pulse line or a difference thereof, provided that the measurement signal supplied by the pressure sensor is influenced by a provided in the diaphragm bluff body and that the measurement signal at least with respect to a contribution to the measurement signal by the bluff body is evaluated.

The object is solved accordingly with a device having the features of claim 8. For this purpose, in a pressure transducer, the at least with a high pressure and a low pressure pulse line to a line in a range before and after a point of discontinuity, in particular a diaphragm, is connected or connectable and which is determined by means of a pressure transducer included pressure sensor for outputting a measurement signal with respect to a pressure in the high or low pressure pulse line or a difference thereof, provided that of the pressure sensor during operation, the measurement signal available is influenced by a bluff body provided in the region of the diaphragm and that the measurement signal can be evaluated by the bluff body at least also with respect to a contribution to the measurement signal.

Characterized in that the measurement signal is "evaluated at least in relation to a contribution to the measurement signal through the bluff body" or a multiple evaluation of the measurement signal is possible, namely on the one hand according to one or more known in the art variants and on the other hand, at least The additional evaluation increases the quality of the detection of a sensor error, eg due to clogging of the impulse lines, membrane abrasion, membrane deposits or the like The bluff body leads to an additional, characteristic, higher-frequency signal component in the measurement signal is an evaluation of the measurement signal "at least also with respect to a contribution to the measurement signal by the bluff body" in particular possible that higher-frequency signal components of the measurement signal are evaluated.

Relationships used in subclaims indicate the further development of the subject of the main claim by the features of the respective subclaim; they should not be construed as a waiver of obtaining independent, objective protection for the feature combinations of the dependent claims. Furthermore, with a view to an interpretation of the claims in a closer concretization of a feature in a subordinate claim, it is to be assumed that such a restriction does not exist in the respective preceding claims. It is preferably provided that by means of an analysis ^device as a contribution to the measurement signal by the bluff body, a higher-frequency component of the measurement signal, referred to hereinafter as the vortex shedding frequency or range around a vortex shedding frequency, is evaluated by comparison with a reference value generated from the measurement signal or a predetermined or predefinable reference value and depending on the result of the comparison, a predetermined or predefinable action is triggered. Thus, when the vortex shedding frequency detected or a characteristic spectrum or the like in the field of vortex shedding frequency corresponds to an expected value within predetermined or predeterminable limits, the expected ^¬ te value is specified by the reference value, a quali ^¬ fied evaluating the higher-frequency component of the Messsig- is Nals with regard to a diagnosis possible.

According to a further preferred embodiment, it is provided that alternatively or additionally by means of an analysis device, a low-frequency component of the measurement signal is evaluated separately from a higher-frequency component of the measurement signal resulting as contribution by the bluff body. Thus, as an alternative or in addition to the above-described evaluation of the higher-frequency component of the measurement signal, a simultaneous or at least independent evaluation of a low- and a higher-frequency component of the measurement signal takes place.

Furthermore, it is provided that a characteristic value is determined by means of the analysis device for the low-frequency component and the higher-frequency component of the measurement signal, and either each characteristic value or a difference between the two characteristic values is compared with a predetermined or specifiable reference value and a predetermined one depending on the result of the comparison or predeterminable action is triggered. In contrast to the evaluation of the higher-frequency component of the measurement signal described above and the triggering of an action as a function of the result of the evaluation, both the low-frequency and the low-frequency component are evaluated here the higher-frequency portion of the measurement signal is taken into account, wherein a characteristic value is formed for each examined portion of the measurement signal and either each characteristic value or a difference between the two characteristic values is compared with a predetermined or predefinable reference value. Depending on the result of this comparison, then, as already described above, a predetermined or predefinable action, for. B. ei ^¬ ne optical or acoustic display that represents the result of the comparison triggered.

According to a further preferred embodiment, it is provided that a flow calculation with determination of a flow value is carried out by means of the analysis device with respect to the measurement signal. On the one hand, the higher frequency position, which can be determined with a spinal cord diagnosis, becomes

Vortex frequency used, on the other hand, a differential pressure diagnosis. The determined flow value or the difference of the flow values is then compared with a predetermined or predefinable reference value. Depending on the result of the comparison with respect to the flow value, then, in a quasi-downstream examination, either the higher-frequency component of the measuring signal, as described above for explaining the originally filed claim 2, the low-frequency component alone, or the low-frequency and the high-frequency Proportion of the measurement signal, as described above for explaining the originally filed claim 3, evaluated.

The embodiment of the method thus provides, in particular, for a flow calculation to be carried out initially and for one or more flow values determined or deviating from an expected value represented by the reference value to deviate or deviate from a predefined threshold value as determined by the reference value, as it were to control the flow calculation nor the measurement signal influenced by the bluff body is used, either by evaluating only the higher-frequency portion of the measurement signal, and thus essentially on the contribution limited by the bluff body, or only the low-frequency ^¬ th portion of the measurement signal, which is influenced by the low body of the bluff body, or by evaluating the low- and the höufherfrequenten portion of the measurement signal, so that quasi a threefold review results.

For example, the flow calculation is only performed by Auswer ^¬ processing of the differential pressure. To check is then checked whether the vortex shedding generated by the bluff body is present in the measurement signal at the expected by the predetermined flow rate frequency.

The method described above and explained further below is preferably implemented as software, so that the invention also relates to a computer program with computer-executable program code instructions for implementing the method outlined above or explained below and a computer program product, in particular a storage medium or the like, having such a computer program applies.

To carry out the method outlined above and explained below, the already mentioned analysis device is provided, which in particular is an analysis device with a computer program of the type described above.

With regard to the analysis device, it is further preferred for the latter to comprise a diagnostic parameter calculation unit provided with a predetermined or predefinable reference value for determining a diagnostic characteristic value with respect to the measurement signal and comparing the result of the comparison to the activation of the evaluation either the higher-frequency, the low-frequency or the low-frequency and the higher-frequency portion of the measurement signal switching means provided (which can also be implemented by a computer program) can be controlled. In such a design of the pressure transmitter, Namely, the analysis device comprised thereof, the check of the pressure transducer, if the diagnosed characteristic value determined in the diagnosis characteristic calculation deviates from the expected value by more than a predetermined or predefinable threshold, also automatically triggered by the above-mentioned switching means driven depending on the result of the comparison of the diagnosis characteristic be or are ^¬ controllable. With the activation of the respective switching means is either the evaluation of the higher-frequency component of the measurement signal or the low-frequency component of the measurement signal or the evaluation of the low and the higher-frequency component of the measurement signal and possibly triggering ei ^¬ ner action with regard to these downstream evaluation ak ^¬ tivated.

Accordingly, it is further preferred for the pressure transducer to comprise a display unit which is capable of displaying a result of the evaluation of the measurement signal either with respect to the contribution to the measurement signal by the baffle body and / or to display a result of the evaluation of the higher-frequency component of the measurement signal. or is determined and prepared for displaying a result of the separate evaluation of the low and higher frequency portion of the measurement signal.

The advantage of the invention and one of its refinements, in which the higher-frequency component is not used for determining the flow rate, therefore consists in particular in improving the quality in detecting the clogging of impulse lines, membrane damage or the like, an uncalibrated bluff body whose exact match with a given geometry is therefore rather of minor importance, is usable. As already described above, the baffle body present in the region of the diaphragm leads to a change in the spectrum of the measurement signal, in particular in the higher-frequency range of the measurement signal. By analyzing it, in particular by examining the position and amplitude of, or in the area of so-called vortex shedding, Frequency, although no absolute flow value is available, but at least one diagnostic information that is evaluable with respect to a detection of the blockage of individual or multiple pulse lines.

In continuation of this approach, as described above, the analysis device continuously checks the blockage of the differential pressure lines by analyzing low-frequency signal components of the measurement signal. Parallel or intermittent can be on the basis of the measurement signal

Flow value can be calculated by means of a preferably also included by the analysis device flow calculation unit. If a blockage is detected, which is detected either during the analysis of the low-frequency signal components of the measurement signal or if the flow value deviates from an expected value or also on the operator's request, the higher-frequency signal component of the measurement signal is evaluated to check the blockage. This is z. For example, the power density in a certain frequency range of the higher-frequency signal component is examined. In short, this additional analysis particularly examines the effect of vortex shedding. Due to the majority of the evaluation and diagnostic criteria, their mutual monitoring in the sense of a plausibility check and a calibration are possible. In this context, z. B. provided according to a further aspect of the invention that the amplitude of the higher-frequency signal component during a "good phase", so if there is no evidence of constipation due to the remaining diagnostic criteria, is learned and tracked in the evaluation of the low-frequency signal components.

For the theoretical background of the approach according to the invention, it should be mentioned that a simple bluff body not only causes different, higher-frequency signal components depending on the gas content of the fluid, but generally increases the noise component in the entire frequency range by additional separation of the fluid and turbulence at the diaphragm. This noise component depends on the degree of clogging of the Transfer pulse lines of varying strength to the differential pressure transducer, so that a bluff body according to the findings of the invention for detecting the clogging of impulse lines is used.

Due to the increased low-frequency noise and the blockage detection using algorithms that relate to low-frequency signal components, simplified. Also, the increased low-frequency noise is to influence the measuring signal through the ram body within the meaning of the above, to the originally filed claim 1 and further into the ^¬ sem sense the blockage detection by means of algorithms relating to such elevated by the bluff body low- An evaluation of the measuring signal "at least also with respect to a contribution to the measuring signal by the bluff body." The result of such an examination can, if necessary, checked by a detailed analysis of higher-frequency signal components that are characteristic of the bluff body, and thus the reliability of the detection can be increased.

Instead of the bluff body, a flow vortex sensor, which also functions as a bluff body in the sense of the present invention, can be used. In connection with the use of a bluff body instead of a vortex sensor or a vortex sensor as a bluff body, an advantage of the approach according to the invention results from the fact that a known vortex sensor requires additional electronics as well as a calibration in order to make the vortex body signal usable for the flow measurement but not the invention. According to the invention, the bluff body or the vertebral body used as a bluff body is not continuously used as a vortex sensor, but only for sensor diagnosis, ie to improve the quality of a detection of a blockage of Wirkdruck- lines or membrane defects. Furthermore, the evaluation with respect to the bluff body is also required only temporarily and according to a preferred embodiment, activated either automatically or manually. Through this non-continuous analysis of higher-frequency components of the measurement signal, the calculation effort can be reduced. In particular, the analysis device need not be designed for the use of two types of sensors simultaneously, so that the same analysis device can be used to determine all diagnostic criteria.

If the amplitude of the vortex frequency is learned and tracked during the "good phase", an inadequate vortex frequency amplitude can also be used to check the obstruction detection by analyzing the low-frequency noise.

An embodiment of the invention will be explained in more detail with reference to the drawing. Corresponding objects or elements are provided in all figures with the same reference numerals.

The or each embodiment is not to be construed as limiting the invention. Rather, numerous modifications and variations are possible within the scope of the present disclosure, in particular those variants and combinations, for example, by combination or modification of individual described in conjunction with the general or special descriptive part and in the claims and / or the drawings Characteristics or elements or process steps for the expert in terms of solving the problem are removable and lead by combinable features to a new subject or to new process steps or process steps, even if they concern manufacturing, testing and working procedures.

Show in it

1 shows a pressure transmitter according to the invention, 2 shows an alternative embodiment of a pressure transmitter according to the invention,

3 shows a further alternative embodiment of a pressure transmitter according to the invention and FIG

4 shows a schematically simplified representation of a bluff body in a line.

FIG. 1 shows, in a schematically simplified illustration, a line 12 through which a fluid 10 flows as an arrow with a point of discontinuity in the form of a so-called (measuring) orifice 14. Upstream and downstream of the measuring orifice 14, impulse or differential pressure lines 16, 18 reach the Line 12 on. With the differential pressure lines 16, 18, a differential pressure transducer 20 is coupled to the line 12. This gives as a measuring signal 22 from a differential pressure measuring signal, which in an analysis device 24, the z. B. in the form of evaluation electronics, first by a preprocessing 26 a preprocessing, ie z. As a filtering and / or digitizing or the like is subjected. After preprocessing, the measuring signal 22 is transferred to a signal memory 28. On the basis of stored in the latch 28 or retrievable from the signal memory 28 measurement signal 22, an evaluation of the same is possible on the one hand with respect to a low-frequency component of the measurement signal 22 and on the other hand with respect to a higher-frequency portion of the Messsig- 22. This is a first and a second evaluation unit 30, 32 provided within the analysis device 24. The functionality of the first evaluation unit 30 can also be described as constipation detection on the basis of the effective pressure ratios. Accordingly, the first evaluation unit 30 and / or its functionality are also referred to by the abbreviation "differential pressure diagnosis." The second evaluation unit 32 is provided for evaluating a higher-frequency component of the measurement signal 22, wherein the higher-frequency Proportion of the measuring signal 22 is influenced by a provided in the region of the diaphragm 14 bluff body 34. By means of the second evaluation unit, therefore, the measuring signal 22 is also evaluated by the bluff body 34 with respect to a contribution to the measuring signal 22. In continuation of the above be ^¬ already designation described is according to the second evaluation unit 32 and / or referred their functionality bearing the symbol "vortex sensor diagnostics". After the bluff body 34, not only the higher frequency component of the measuring signal 22, but, in particular depending on the gas content of the Fluid 10, generally caused by additional detachment of the fluid 10 downstream of the bluff body 34 and turbulence caused by the baffle 34, the noise component in the entire frequency range of the measurement signal 22, also carried out by the first evaluation unit evaluation of the low-frequency component of the measurement signal 22 also refers to a Evaluation of the measuring signal 22 at least also with respect to a contribution to the measuring signal 22 by the bluff body 34.

By the evaluation units 30, 32, a characteristic value is respectively determined for the low-frequency component and the higher-frequency component of the measurement signal 22. Subsequently, either each characteristic value or a difference between the two characteristic values is compared with a predetermined or predefinable reference value. For this purpose, a comparator 36 connected downstream of the evaluation units 30, 32 is provided which also (not shown) comprises a memory for the reference value or has access to a memory area in which the reference value is stored. Depending on the result of the comparison, a predetermined or predefinable action is triggered, z. B. by an optical or acoustic display unit 38 is driven.

The entirety of the units shown in FIG. 1 without the line 12 along their entire longitudinal extension and without the differential pressure lines 16 and 18 is also referred to as a pressure transmitter 40. 2 shows a further embodiment of the pressure transducer 40 of Figure 1, wherein is not subsequently received again in connection with the loading ^¬ scription of FIG.1 explained units.

In contrast to the illustration shown in FIG 1, the pressure sensor can ^¬ 20 now provide as a measurement signal 22 is not only a differential pressure measuring signal but also an absolute pressure measurement signal 42nd Differential pressure measuring signal and absolute pressure measuring signal 42 are still, unless otherwise stated explicitly, summarized under the generic term measuring signal 22. 2, a diagnostic characteristic calculating unit 44, also referred to as "flow rate calculating unit differential pressure", is shown in FIG the signal memory 28 in order to carry out a flow calculation based on the measurement signal 22, in particular on the basis of the differential pressure measurement signal comprised by the measurement signal 22. As a result of the flow calculation, a flow value 46 is supplied directly or indirectly to the display unit 38. If the indicated flow value 46 or the one with the or both evaluation units 30, 32 deviates from an expected flow value (diagnostic limit value) by more than a predefined or specifiable threshold value, the blockage detection can be activated in accordance with the approach according to the invention, ie the functionality already implemented in the Connection with FIG 1 has been explained, be retrieved.

For this purpose, switching means 48, 50 shown as switches are provided in the schematically simplified representation, which are either manually by a user - after evaluation of the presented via the display unit 38 flow value or diagnostic characteristic - or automatically - after comparison

(eg by a dedicated comparator) of the flow value 46 or diagnostic characteristic value with respect to a deviation from an expected value by more than a predetermined value. or specified threshold value can be actuated. The switching means 48, 50 can be operated either individually or together. In the case of a single actuation, each functionality implemented by the evaluation units 30, 32 can be retrieved individually, ie the measurement signal 22 can be analyzed with respect to the low-frequency or higher-frequency signal component. The result of evaluation is an indication in respect of any possible clogging in the rich Be ^¬ the impulse lines 16, 18 or in the region of the aperture 14 or a Membranabrasion or the like. With the diagnostic criterion obtainable by means of one or each evaluation unit 30, 32 with respect to any blockage that may be present, the flow signal 46 can be checked for plausibility. If both switching means 48, 50 are activated at the same time, it is preferably provided that the characteristic value determined by both evaluation units 30, 32 with respect to the lower or higher-frequency signal component of the measurement signal is compared with a predetermined or predefinable reference value after the difference between the two characteristic values has been formed , wherein the comparison with the reference value represents the diagnostic criterion with regard to a present or non-existing blockage and is forwarded to the display unit 38.

The backward-pointing arrows starting from the reference 36 to each evaluation unit 30, 32 show that mutual monitoring of the diagnostic features and / or calibration within the analysis device 24 is possible and provided in the manner described.

FIG. 3 shows a further alternative embodiment of the invention

1, instead of the first and second evaluation unit 30, 32, the diagnostic parameter calculation unit 44 already explained in connection with FIG 2 is combined with a further diagnostic parameter calculation unit 45, also referred to as "flow calculation unit vortex sensor." With the diagnostic parameter value calculation unit 44, a flow rate calculation based on the differential pressure is performed. leads. With the further Diagnosekennwertberechnungseinheit 45 an analysis of the Wirbelablösefrequenz in relation to their location in an expected, ie predetermined or predetermined range, performed. All other elements correspond to the elements already explained in connection with FIG. 1 and will not be described again here.

Finally, FIG. 4 shows, in a sectional view of the line 12, a schematically simplified representation of a bluff body 34, as shown in the FIG

Realization of the approach according to the invention could find use. It can be seen from the illustration that the bluff body 34 is arranged in the region of the metering orifice 14. The bluff body 34 has a basic shape in the manner of a prism, wherein base is directed against the flow direction of the fluid 10 in the conduit 12. Other geometries and / or orientations of a bluff body are readily conceivable.

In summary, the present invention can be described as follows: A method for operating a pressure transducer 40 and such a pressure transducer 40 is given, which at least with a high pressure and a low pressure pulse line 16, 18 to a line 12 in the area before and after a point of discontinuity , in particular a diaphragm 14, wherein a pressure sensor 20 encompassed by the pressure transducer 40 provides a measuring signal 22 with respect to a pressure in the high or low pressure pulse line 16, 18 or a difference thereof, in which the measuring signal 22 from a baffle body 34 provided in the region of the diaphragm 14 is influenced and the measuring signal 22 is evaluated or evaluable by the baffle body at least also with respect to a contribution to the measuring signal 22.

Claims

claims

1. A method for operating a pressure transducer (40), at least with a high-pressure and a low-pressure pulse line (16, 18) to a line (12) in a region before and after a discontinuity, in particular a diaphragm (14) connected and wherein a pressure sensor (20) encompassed by the pressure transducer (40) provides a measurement signal (22) with respect to a pressure in the high or low pressure pulse line (16, 18) or a difference thereof characterized in that the pressure sensor (16) supplied measurement signal (22) is influenced by a baffle (34) provided in the region of the diaphragm (14) and that the measurement signal (22) is evaluated by the baffle body (34) at least also with respect to a contribution to the measurement signal (22).

2. The method of claim 1, wherein by means of an analysis device (24) as a contribution to the measurement signal (22) by the bluff body (34) a higher-frequency portion of the measurement signal (22) by comparison with a generated from the measurement signal or predetermined or predetermined Reference value is evaluated and depending on the result of the comparison, a predetermined or predeterminable action is triggered.

3. The method of claim 1, wherein by means of an analysis device (24) a low-frequency component of the measurement signal (22) separated from a contribution by the bluff body (34) resulting higher-frequency component of the measurement signal (22) is evaluated.

4. The method of claim 3, wherein by means of the analysis device (24) to the low-frequency component and the higher-frequency component of the measurement signal (22) a characteristic value is determined and either each characteristic value or a difference between the two characteristic values with a given or predetermined reference value is compared and depending on the result of the comparison, a predetermined or predeterminable action is triggered.

5. The method of claim 2 or 4, wherein by means of the analysis device (24) with respect to the measurement signal (22) a flow calculation with determination of one or more flow values (46) by means of a Wirk ^¬ pressure or Vortex sensor diagnosis and comparison of the same or a difference Flow values with a predetermined or predefinable threshold value is performed and wherein, depending on the result of the comparison, the higher-frequency component of the measurement signal (22) or the lower-frequency and the higher-frequency component of the measurement signal (22) is evaluated.

6. The method as claimed in claim 5, wherein first a flow value (46) is determined and compared with the threshold value by means of a first evaluation unit 30 included in the analysis device (24), wherein a flow rate value (46) is determined by the analysis device (24 ), a flow rate value (46) is determined and compared with the or a further threshold value and a predefined or predeterminable action is triggered, if in both comparisons a flow rate value (46) is determined Overshoot or undershoot of the threshold.

A computer program comprising computer executable program code instructions for implementing the method of any one of claims 1 to 6 when the computer program is run on a computer.

8. Computer program product, in particular storage medium, with a computer-executable computer program according to claim 7.

9. pressure transmitter, the at least one high-pressure and a low-pressure pulse line (16, 18) to a line (12) in a region before and after a discontinuity, in particular a diaphragm (14) connected or connectable and by means of a pressure transducer (40) comprises pressure sensor (20) for outputting a measurement signal (22) with respect to a pressure in the high or low pressure pulse line (16, 18) or a difference thereof, characterized in that the pressure signal from the pressure sensor (20) available (22) is influenced during operation by a bluff body (34) provided in the region of the diaphragm (14) and that the measurement signal (22) can be evaluated by the bluff body (34) at least also with respect to a contribution to the measurement signal (22).

10. Pressure transmitter according to claim 9, with an analysis device (24) provided for carrying out the method according to one of claims 2 to 4, in particular an analysis device (24) with a computer program according to claim 7.

11. Pressure transmitter according to claim 10, wherein the analyzer (24) comprises one for determining one or more flow values (46) by means of an active pressure or vortex sensor diagnosis with respect to the measurement signal (22) and comparing the same or a difference of the flow values with one and provided depending on the result of the comparison for activating the evaluation of the higher frequency or the low and the higher frequency portion of the measuring signal (22) provided switching means (48, 50) are controllable.

12. Pressure transmitter according to one of claims 9 to 11, with a display of a result of the evaluation of the measuring signal (22) with respect to the contribution to the measuring signal (22) by the bluff body (34) and / or to display a result the evaluation of the higher frequency portion of the measurement signal (22) and / or display of a result of the separate evaluation of the low and the higher frequency portion of the measurement signal (22) specific display unit (38).