DE102009000749A1 - Vibration-type measuring transformer i.e. coriolis mass flow meter, operating method, involves indicating that detected mass flow value is not reliable when variations of mass flow value lies below preset threshold value - Google Patents

Abstract

The method involves detecting a mass flow value of medium flowing through a mass discharge pipe of a measuring transducer, and detecting variations of the mass flow value and/or resonance frequencies of the mass discharge pipe for reliability testing of the mass flow value. The reliability testing indicates that the detected mass flow value is not reliable when the variations of the detected mass flow value lies below a preset threshold value and/or when the variations of the detected resonance frequencies lies above another preset threshold value.

Description

The The invention relates to a method of operating one of a medium flowed through transducer of the vibration type.

One Vibration-type transducers, in particular a Coriolis mass flowmeter, is preferably used to control a mass flow independently from the properties of the flowing medium, such as density, Viscosity and / or flow profile to determine. Another advantage of Coriolis mass flow meters is in that you have the mass flow of one through the transducer flowing medium can measure without the actual mass flow influenced by a sensor immersed in the mass flow. An embodiment of a Coriolis mass flowmeter comprises a mass flow tube, which is designed as a pipe bend and has an inflow and an outflow. The pipe bend is at his the end corresponding to the inflow or outflow, and stored in such a swingable manner in an intermediate region that he swing perpendicular to a plane defined by the pipe bend can. If the pipe bend is excited to vibrate with its resonance frequency, a Coriolis force acts on the flowing in the pipe bend Medium. Depending on how big the mass flow is, results due to the Coriolis force a phase shift of the oscillation the two legs of the pipe bend to each other, the calculation the mass flow is used.

at In another embodiment, the medium flows through at the same time two pipe bends whose planes are arranged parallel to each other are and with a phase shift of 180 ° with their respective resonant frequency are excited to vibrate. The provision of two pipe bends has the advantage that the Mass flow tube during the exciter vibration is nen Mass center maintains and thereby a transmission the excitation oscillation is suppressed to a pipe system, where the Coriolis mass flowmeter is connected.

A change Mass flow inevitably leads to a change the resonant frequency of the mass flow tube, whereupon in the Usually the excitation frequency of the mass flow pipe to the changed Resonant frequency is adjusted.

In the US 2006 0058971 A1 For example, means are proposed for a reliability check of the detected mass flow value, wherein among other things the instantaneous mass flow value and the temporal fluctuation of the instantaneous mass flow value are used as means for the reliability test. If an abrupt change of the mass flow value takes place or if the time change of the mass flow value increases above a predetermined threshold value, instead of the detected mass flow value, a corrected mass flow value is determined, which is displayed instead of the detected mass flow value. The detected mass flow value is replaced with a corrected mass flow value even if the detected mass flow value is outside a predetermined interval. A lower threshold for the interval is zero, and an upper threshold is predetermined depending on a maximum value of mass flow.

A disadvantage of in the US 2006 0058971 A1 The solution described is that it only allows an insufficient reliability test, since only a small number of process parameters are used to check the mass flow value.

The The object of the invention is a reliability test of the mass flow value to thereby increase the mass flow value to specify.

The The object of the invention is achieved by a method for operating the Instrument transformer solved for the reliability test of the mass flow value detected, the temporal fluctuation of the Resonance frequency and / or the temporal fluctuation of the detected Mass flow value used. There is the reliability test indicates that the recorded mass flow value is not reliable is, if the temporal variation of the detected mass flow value is below a predetermined first threshold or if the temporal fluctuation of the detected resonant frequency above a predetermined second threshold.

According to the invention Thus provided that the mass flow value a predetermined may not exceed the first threshold and / or that the temporal fluctuation of the resonance frequency a predetermined second threshold may not exceed, so that the Mass flow value of a reliability test withstand. This has the advantage that the mass flow value thereby becomes more reliable by adding two new process parameters in perform the reliability test.

According to a preferred development of the invention, it is provided that the first threshold value and / or the second threshold value are changed during the operation of the measuring transducer. This allows the transducer during the measurement process on the respective medium, the mass flows through the flow tube of the transducer, to be adjusted.

According to one further preferred embodiment of the invention is provided that the second threshold depending on the current Resonant frequency is set. This is advantageous because smaller ones Resonant frequencies smaller fluctuations and larger Resonant frequencies have larger fluctuations.

According to one preferred embodiment of the invention is provided that if the temporal fluctuation of the mass flow value and the temporal Fluctuation of the resonant frequency not within a predetermined range Time interval are recorded, the reliability test the measured mass flow value is not reliable classifies. Should the temporal fluctuation of the resonance frequency with a relatively large time difference to the temporal fluctuation the mass flow value can be detected and / or vice versa an intermediate change of one of the two process parameters can not be excluded, resulting in a falsified mass flow value would result.

According to one preferred embodiment of the invention is provided a mass flow value less than zero is determined by the Reliability test as not reliable is classified. A mass flow value less than zero would a reversal of the flow direction, which in principle to operate of the transducer and the actual function of the mass flow tube, the is integrated in a pipe system, is not provided.

Farther is preferably provided that in the event that the mass flow value above a predetermined third threshold, the reliability test the measured mass flow value is not reliable classifies. In this way, maximums that are due were determined by corrupted process parameters than not be classified reliably. The third threshold is expediently as a function of a maximum value of mass flow and is preferably ≥ 50% and ≦ 90%, more preferably ≥ 60% and ≦ 75% a maximum value of mass flow. Generally you can note that the third threshold is application specific, thus determined depending on the respective application can be. Thus, he can also outside the previously specified Values are.

According to one further embodiment of the invention is preferably also provided that the process parameters according to a predetermined order for a reliability check will be recorded. A preferred order of the detected process parameters means preferably that first the temporal variation of the mass flow value and then the temporal fluctuation of the resonance frequency checked become. This is advantageous because the time variation of the mass flow value much more often the requirements of the reliability test does not withstand the demands on the temporal Fluctuation of the resonance frequency. So will in case of a time fluctuation of the mass flow rate a reading correction earlier and initiated after fewer process steps.

Farther is according to a preferred embodiment of Invention provided that in case of unreliable Mass flow value the mass flow value as long as not displayed until the reliability test is a mass flow value declared reliable and the reliable mass flow value instead of the directly before that declared unreliable Mass flow value is used. By this method can falsifying fluctuations in the mass flow rate in the Be smoothed afterwards.

According to one further preferred embodiment of the invention is provided that the reliability test in predetermined Time intervals, preferably every 10 s performed becomes. Furthermore, it is preferred that the time intervals during of the operation are adjustable. This has the advantage that the reliability test also in the case of flowing through the medium in the transducer or in the mass flow pipe to the temporal fluctuations the mass flow rate or the temporal fluctuations of the resonant frequency of appropriate medium can be adapted.

The Invention will become apparent from the following drawings explained.

It demonstrate:

1 FIG. 1 shows a first flow chart for carrying out a method according to a preferred exemplary embodiment of the invention for operating a vibration-type measuring instrument through which a medium flows, and FIG

2 FIG. 2 shows a second flowchart for carrying out a measurement value correction of an unreliable mass flow value according to a preferred exemplary embodiment of the invention for operating a vibration-type measuring instrument through which a medium flows.

A flow chart of a preferred embodiment of a reliability test according to the invention is shown in FIG 1 shown. The reliable lichkeitsprüfung 2 leads to a first processing 3 which first detects a mass flow value and a resonance frequency for the mass flow pipe, and the detected mass flow value and the detected resonance frequency to a first branch 4 which checks whether the mass flow value and the resonance frequency have been detected in a predetermined time interval. If this is not the case, then there will be a second processing 5 which corrects the mass flow value.

After the correction becomes a third processing 6 called, which introduces a time delay T in the flowchart, wherein the time delay T is predetermined and can be changed before and during the measurement process. After the introduction of the time delay T by the third processing 6 Again, another mass flow value through the first processing 3 detected and the verification of the detected mass flow value in the first branch 4 takes place again.

On the other hand, if the mass flow rate and the resonance frequency have been detected within the predetermined time interval, then a second branch will be detected 7 which checks whether the detected mass flow value is negative or greater than a third threshold, which is preferably 65% of a predetermined maximum value for the mass flow value. If one of the two demands on the detected mass flow value is fulfilled, this leads to the call of the second processing 5 which corrects the mass flow value and after the correction via the third processing 6 back to the first processing 3 leads to recapture the process parameters.

If the detected mass flow value is greater than zero and less than the third threshold, ie, less than 65% of the predetermined maximum value for the mass flow value, this results in a third branch 8th by checking whether the time variation of the mass flow value is below a predetermined first threshold, wherein the time variation of the mass flow value is determined in the following manner:
The most recently detected mass flow value is subtracted from the mass flow value previously detected and the difference is subtracted by that in the third processing 6 shared time delay divided. If the amount of the mass flow value determined in this way is greater than the predetermined first threshold value which can be freely set before or during the measuring process, this means that the measuring process solidifies and leads to the second processing 5 that corrects the detected mass flow value.

If the amount of time variation of the mass flow value is less than the first threshold, this results in a fourth branch 9 , which is the temporal variation of the resonant frequency caused by the first processing 3 was recorded, checked. If the amount of the time fluctuation of the mass flow value is below a predetermined second threshold which can be freely set before or during the measuring process, this leads to a fourth processing 10 , which adjusts an excitation frequency of a mass flow tube of the transducer to the changed resonance frequency and then the temporal change of the resonance frequency to the second processing 5 leads, which then determines a corrected mass flow rate due to the changed resonant frequency.

Should the temporal variation of the resonant frequency be less than the second threshold, this results in a re-detection of the mass flow value by means of the first processing 3 , The second threshold is predetermined as a percentage of the instantaneous resonant frequency and is preferably 5% of the instantaneous resonant frequency of the mass flow tube.

In 2 is the second flowchart 11 a correction function, which gives an unreliable mass flow value according to the second processing 5 (please refer 1 ) corrected. The flowchart 11 starts with a start terminator 12 which is called whenever the second processing 5 a mass flow value is declared unreliable.

The beginning terminator 12 leads to a fifth processing 13 , which was first determined for how many times the correction function was called. Subsequently, in the fifth processing 13 the previously detected mass flow value associated with a detection time t _i , where i is an index for the number of the called correction function (ṁ = ṁ (t _i )). Subsequently, a fifth branch 14 which determines which time elapsed between the current and the last call of the correction function.

If the elapsed time is less than the time delay (t _i -t _i-1 <T), this is an indication that no further mass flow value was detected between the current and the past mass flow value, since only after the time delay T is a mass flow value is detected. This leads to the execution of a sixth processing 15 which sets the corrected mass flow value to zero (ṁ (t _i ) = 0) and finally the correction function by the terminal terminator 17 completed.

If, on the other hand, the elapsed time between two calls of the correction function is greater than the time delay (t _i -t _i-1 > T), then this is an indication that at least one reliable mass flow value is detected between the last call and the current call of the correction function has been. This mass flow value declared reliable is used in place of the past mass flow values declared by the correction function for unreliable, and then the correction function by the terminal terminator 17 completed.

1

flow chart

2

reliability test

3

First processing

4

First branch

5

Second processing

6

third processing

7

Second branch

8th

third branch

9

Fourth branch

10

Fourth processing

11

Flowchart of the second processing 5 (Correction function)

12

beginning terminator

13

Fifth processing

14

Fifth branch

15

Sixth processing

16

Seventh processing

17

Final terminator of the second processing 5 (Correction function)

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• US 20060058971 A1 [0005, 0006]

Claims (10)

A method of operating a vibrating type transducer comprising a mass flow tube through which a medium flows, detecting a mass flow value for the flowing medium, and performing a reliability test on the detected mass flow value ( 2 ), characterized in that for the reliability test ( 2 ) the temporal fluctuations of the mass flow rate are detected and / or a resonant frequency of the mass flow pipe through which flow is detected and the temporal fluctuations of the detected resonant frequency are determined, wherein the reliability test ( 2 ) indicates that the detected mass flow value is not reliable if the temporal fluctuations of the detected mass flow value are below a predetermined first threshold, or if the temporal fluctuations of the detected resonant frequency are above a predetermined second threshold. Method according to claim 1, characterized in that that the first threshold and the second threshold during the operation of the transducer can be adjusted. Method according to claim 1, characterized in that that the second threshold depending on the current Resonant frequency is set. Method according to one of the preceding claims, characterized in that the reliability test ( 2 ) indicates that the detected mass flow value is not reliable if the temporal fluctuations of the resonance frequency and the time variation of the mass flow value are not detected within a predetermined time interval. Method according to one of the preceding claims, characterized in that the reliability test ( 2 ) indicates that the detected mass flow value is not reliable if the detected mass flow value is less than zero. Method according to one of the preceding claims, characterized in that the reliability test ( 2 ) indicates that the detected mass flow value is not reliable if the mass flow value is above a predetermined third threshold, preferably ≥ 50% and ≤ 90%, more preferably ≥ 60% and ≤ 75% of a maximum value of mass flow. Method according to Claim 6, characterized that the third threshold depends on a maximum value the mass flow rate is determined. Method according to one of the preceding claims, characterized in that for the reliability test ( 2 ) the temporal variation of the mass flow rate and the temporal fluctuation of the resonance frequency are sequentially checked. Method according to one of the preceding claims, characterized in that in the case of an unreliable Mass flow value, a subsequent and reliable Mass flow value instead of the unreliable mass flow value is used. Method according to one of the preceding claims, characterized in that the reliability test ( 2 ) is performed at predetermined time intervals, and that the time intervals are adjustable, and that the time intervals are adjustable during operation.