DE102021133787A1 - Detection of foreign bodies in flowing measurement media - Google Patents

Abstract

The invention relates to a measuring system (1) and a measuring method for the reliable detection of foreign bodies (4) in measuring media (2) which flow through line sections (3). For this purpose, the measuring system (1) comprises: a first field device (11), which measures the respective measured value (m1) of a first process variable in the line section (3); A second field device (11', 12) which determines the measured value (m1', m2) of either the same process variable or of a second process variable of the measuring medium (2) in the line section (3); And an evaluation unit (13) to detect any foreign body (4) at least on the basis of the first measured value (m1) and the second measured value (m1', m2), for example by correlating the measured values (m1, m1', m2 ). The foreign body detection according to the invention allows any foreign bodies (4) to be detected within the process system without additional measuring equipment, provided that the process variable(s) is/are to be monitored as part of the process per se. As a result, the process plant can be operated more safely and efficiently overall.

Description

The invention relates to a measuring system and a measuring method for the reliable detection of foreign bodies in flowing media, with only a small amount of measuring equipment being required.

In process automation technology, field devices are often used that are used to record or influence process variables. Corresponding sensors or measuring principles are used to record the respective process variable, which are used, for example, in fill level measuring devices, flow measuring devices, pressure and temperature measuring devices, pH redox potential measuring devices, conductivity measuring devices, or comparable devices. Accordingly, they record the level, flow rate, pressure, temperature, pH value, redox potential or conductivity as process variables. A wide variety of such field device types are manufactured and sold by the Endress + Hauser group of companies.

In addition to the aforementioned process variables, there are also those that cannot be recorded at all by a single field device or only with great technical effort. This includes, among other things, the detection of any foreign bodies in the measurement media that flow through the corresponding line sections in process systems. Depending on the type of process plant or depending on the area of application, the line section in which any foreign bodies are to be detected can be a closed pipe, a section of an open line or an open body of water. Foreign bodies are particularly critical in the food industry, for example, where, for example, metal shavings or shards in liquid food must be avoided at all costs from a health perspective. The invention is therefore based on the object of being able to reliably detect any foreign bodies in measurement media that flow through line sections with as little measurement equipment as possible, even at high flow speeds.

• - Ein erstes Feldgerät, das ausgelegt ist, um einen ersten Messwert einer ersten Prozessgröße im Leitungsabschnitt zu messen,
• - ein zweites Feldgerät, das ausgelegt ist, um im Leitungsabschnitt einen zweiten Messwert von entweder der ersten Prozessgröße oder von einer zweiten Prozessgröße des Messmediums zu bestimmen, und
• - eine Auswerte-Einheit, die ausgelegt ist, um zumindest anhand des ersten Messwertes und anhand des zweiten Messwertes einen etwaigen Fremdkörper zu detektieren, beispielsweise anhand einer Korrelation zwischen den Messwerten, einer zeitlichen Faltung der Messwerte, oder einer Laplace- bzw. Z-Transformation.

The invention solves this problem with a measuring system for the detection of solid-like foreign bodies in a measuring medium, which flows through a line section of a pipe, for example. The measuring system includes at least the following components:

• - A first field device that is designed to measure a first measured value of a first process variable in the line section,
• - a second field device, which is designed to determine a second measured value of either the first process variable or of a second process variable of the measuring medium in the line section, and
• - an evaluation unit that is designed to detect any foreign body at least based on the first measured value and based on the second measured value, for example based on a correlation between the measured values, a temporal convolution of the measured values, or a Laplace or Z transformation .

Within the scope of the invention, the term “unit” is understood in principle to mean any electronic circuit or hardware that is suitably designed for the intended purpose. Depending on the requirement, it can therefore be an analog circuit for generating or processing corresponding analog signals. However, it can also be a digital circuit such as an FPGA or a storage medium in cooperation with a program. The program is designed to carry out the corresponding procedural steps or to apply the necessary arithmetic operations of the respective unit. Specifically, the evaluation unit can also be, for example, a process control center of the process installation or a decentralized server.

The foreign body detection according to the invention allows any foreign bodies to be detected within the process system without additional measuring equipment, provided that the process variable(s) is/are to be determined per se within the framework of the process. As a result, the process plant can be operated more safely and efficiently overall.

• - Bestimmung eines ersten Messwertes einer ersten Prozessgröße des Messmediums im Leitungsabschnitt mittels des ersten Feldgerätes,
• - Messung eines zweiten Messwertes der ersten Prozessgröße oder einer zweiten Prozessgröße des Messmediums im Leitungsabschnitt mittels des zweiten Feldgerätes, und
• - Detektion des etwaigen Fremdkörpers anhand des ersten Messwertes und anhand des zweiten Messwertes.

Corresponding to the measuring system according to the invention, the object on which the invention is based is also achieved by a method for detecting any foreign bodies using the measuring system. Accordingly, the process comprises the following process steps:

• - Determination of a first measured value of a first process variable of the measuring medium in the line section by means of the first field device,
• - Measurement of a second measured value of the first process variable or a second process variable of the measuring medium in the line section by means of the second field device, and
• - Detection of any foreign body based on the first measured value and based on the second measured value.

• - auf Basis des TDR-Verfahrens („Time Domain Reflectometry“), wie beispielsweise in der Veröffentlichungsschrift EP 0622 628 A2 beschrieben ist,
• - analog zu Radar-basierter Abstandsmessung auf Basis eines Pulslaufzeit-Verfahrens, oder
• - auf Basis von Phasenmessung, wie unter anderem in der Veröffentlichungsschrift DE 10 2017 130728 A1 beschrieben ist,

auszulegen, da diese Verfahren sehr empfindliche Messungen ermöglichen. Da auch die Dichte sehr hochaufgelöst messbar ist, kann das erste Feldgerät auch als Dichtemessgerät ausgelegt werden, um als erste Prozessgröße eine Dichte des Messmediums im Leitungsabschnitt zu messen.Basically, within the scope of the invention, it is not firmly prescribed which specific process variable the individual field devices of the measuring System must detect in order to implement the inventive method can. However, a correlation can be recorded more reliably the more sensitively the corresponding field devices can record the measured values. If the first field device is designed as a dielectric value measuring device, for example, in order to determine a dielectric value of the measurement medium as the first process variable, it is advantageous to use this

• - based on the TDR method (“Time Domain Reflectometry”), as for example in the publication EP 0622 628 A2 is described,
• - analogous to radar-based distance measurement based on a pulse propagation time method, or
• - based on phase measurement, as inter alia in the publication DE 10 2017 130728 A1 is described,

interpreted, since these methods allow very sensitive measurements. Since the density can also be measured with very high resolution, the first field device can also be designed as a density measuring device in order to measure a density of the measurement medium in the line section as the first process variable.

In a first variant of the measuring system according to the invention, the second field device can be designed to correspond to the first field device, so that the second field device also determines the first process variable of the measuring medium. In order to take into account the flow rate of the measurement medium or any foreign body, the second field device in this embodiment variant must be arranged in the line section at a defined distance from the first field device in relation to the direction of flow of the measurement medium. Alternatively, the second field device can be designed as a flow meter in order to measure a flow of the measurement medium in the line section as the second process variable. In this case it is irrelevant where the second field device is arranged in the line section in relation to the first field device.

Depending on the type of flow measurement (mass flow, volume flow) and depending on the type or physical state of the medium, various measuring principles are available for measuring the flow of flowing media in the corresponding line sections: A Coriolis-based measuring method is, for example, in the patent EP03241000B1 shown. The magnetic-inductive measuring principle is described in the publication EP 00969268 A1 themed. An ultrasonic-based measurement method is in the international publication WO 2014/001027 A1 shown. A flow sensor working according to the thermal measurement method is described, for example, in the international patent application WO 2014139786 A1 shown. Depending on the measurement method, the flow is determined in the form of a volume flow, for example in m ³ /s. Among other things, with the magnetic-inductive measuring method and with ultrasonic-based measurement, the flow in the line section is determined as a volume flow. If the flow meter is designed according to the Coriolis measuring principle or according to the thermal measuring principle, it determines the flow in the pipe section as gross mass flow.

• 1: Ein erfindungsgemäßes Mess-System zur Detektion etwaiger Fremdkörper in einem strömenden Messmedium.

The invention is explained in more detail with reference to the figure below. It shows:

• 1 : A measuring system according to the invention for detecting any foreign bodies in a flowing measuring medium.

For an understanding of the invention, 1 a pipeline section 3 is shown, through which a measuring medium 2 flows at a controlled flow rate v. In this case, the pipeline section 3 is part of a process installation that is used, for example, to process food.

The flow velocity v or the mass flow M' (in kg/s or a comparable unit) or the volume flow V' (usually in m ³ /s) is usually used as a process variable to control the process plant or the processing process. of the measuring medium 2 through the pipeline section 3 to be determined. Accordingly, a flow meter 12 is arranged on the pipeline section 3 in order to be able to determine the corresponding measured value m2. For example, a device that works according to the thermal principle or an ultrasound-based device can be used as the flow meter 11 .

In order to pass on the currently measured flow rate value m2, the flow meter 12 is connected to a higher-level evaluation unit 13, such as e.g . B. connected to a local process control system or a decentralized server. In this way, the evaluation unit 13 can optionally control inflows or outflows to or from the pipeline section 3 so that the flow rate v is regulated accordingly. Other information can also be transmitted via the interface, for example parameterization data for the flow meter 12 or information on the general operating state of the flow meter 12.

For further inline analysis of the measuring medium 2, two further field devices 11, 11' are also arranged on the pipeline section 3 are also in contact with the measuring medium 2 and both determine the same process variable, such as a dielectric value, a pH value or a density of the measuring medium 2. As in 1 is shown, these field devices 11, 11' are also connected to the higher-level evaluation unit 13 via a corresponding interface in order to transmit the corresponding measured values m1, m1'. In this case, the measurement of one of the same process variables by two independent field devices 11, 11' can create redundancy, for example.

Based on at least two of the in 1 Field devices 11, 11', 12 shown in connection with the higher-level evaluation unit 13 can be used according to the invention to form a measuring system 1 which, in addition to the process variables of the individual field devices 11, 11', 12, also detects any unwanted foreign bodies 4 in the Measuring medium 4 can detect. As a result, additional field devices such as cameras or scanners, which are used specifically to detect any foreign bodies 4 in the measurement medium, can be dispensed with. For this purpose, according to the invention, the evaluation unit 13 assesses whether the measured values m1, m1′, m2 of at least two of the field devices 11, 11′, 12 correlate in a currently defined manner.

If the measured values m1, m1', m2 have a corresponding correlation, the presence of a foreign body 4 can be inferred with a high degree of probability. Depending on which process variable(s) the correlation calculation is/are based on, an inverse correlation between the corresponding measured values m1, m1', m2 can also indicate a foreign body 4. An inverse correlation, which can be traced back to foreign bodies 4 in the measurement medium 2, is present, for example, if one of the field devices 11, 11' measures an increased dielectric value while the flow meter 12 measures a reduced flow velocity v. When assessing whether the measurement medium 2 in the pipeline section 3 includes a foreign body 4, the flow velocity v of any foreign body 4 or the delayed influence of the foreign body 4 on the individual measured values m1, m1' must also be taken into account.

The flow velocity v can, for example, be included in the foreign body detection in the form of the flow measurement values m2 of the flow measuring device 12 . Alternatively, the flow rate v can be included indirectly by the fact that those two field devices 11, 11' of the measuring system 1 according to the invention, the correlation of which is checked, determine the same process variable, but are arranged at a defined distance ΔL from one another in relation to the direction of flow of the measuring medium 2 , as in 1 is shown. In this case, the measured values m1, m1′ of these two field devices 11, 11′ are to be subjected to a corresponding temporal convolution in advance, depending on the type of subsequent correlation calculation. In this embodiment variant, it is also possible for both field devices 11, 11' to determine the same process variable, but with a different measuring principle. If both field devices 11, 11' determine the dielectric value, for example, one of them can be designed based on the TDR method, for example, while the other field device 11, 11' determines the dielectric value by means of phase measurement. This creates another form of redundancy.

Any correlation can be determined more reliably the higher the resolution with which the field device 11, 11', 12 can acquire the measured value m1, m1', m2. Accordingly, in the event that, in addition to the flow rate measurement value m2, the dielectric value of the measurement medium 2 is recorded as measurement values m1, m1', it is advantageous if the corresponding field devices 11 11' are based on a high-frequency measurement principle, such as the TDR principle, as this enables highly accurate measurement.

The foreign body detection according to the invention makes it possible to react appropriately within the process plant to any foreign bodies 4 that may be detected: If a foreign body 4 is detected, the evaluation unit 13 can, for example, cause a shut-off valve, which is located behind the foreign body 4 or the field devices 11 in the direction of flow, 11', 12 is to be closed so that the foreign body 4 is not unintentionally also filled. Or the measuring medium 2 can be diverted in the direction of flow downstream of the field devices 11, 11', 12 into a bypass, via which any rejects are disposed of. As a result, the process plant can be operated more safely and efficiently overall.

Reference List

1

measuring system

2

medium

3

line section

4

foreign body

11

First field device

11'

Second field device

12

flow meter

13

evaluation unit

m1

Measured value of the first field device

m1'

Measured value of the second field device

m2

Flow meter reading

v

flow rate

ΔL

Distance between the gauges

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• EP 0622628 A2 [0008]
• DE 102017130728 A1 [0008]
• EP 03241000 B1 [0010]
• EP 00969268 A1 [0010]
• WO 2014/001027 A1 [0010]
• WO 2014139786 A1 [0010]

Claims (9)

Measuring system for detecting foreign bodies (4) in a measuring medium (2) which flows through a line section (3), comprising: - A first field device (11), which is designed to measure a first measured value (m1) of a first process variable in the line section (3), - a second field device (11', 12), which is designed to determine a second measured value (m1', m2) of either the first process variable or of a second process variable of the measuring medium (2) in the line section (3), and - an evaluation unit (13) which is designed to detect any foreign body (4) at least on the basis of the first measured value (m1) and on the basis of the second measured value (m1', m2). measuring system claim 1 , wherein the evaluation unit (13) is designed to detect the foreign body (4) based on an in particular inverse correlation between the measured values (m1, m1', m2) of the at least two field devices (11, 12) and/or based on a time convolution of the measured values (m1, m1', m2). Measuring system according to one of the preceding claims, wherein at least the first field device (11) is designed as a density measuring device in order to measure a density of the measuring medium (2) in the line section (3) as the first process variable. Measuring system according to one of Claims 1 or 2 , wherein at least the first field device (11) is designed as a dielectric value measuring device in order to determine a dielectric value of the measuring medium (2) as the first process variable, in particular according to a TDR method, according to a pulse propagation time method or by means of phase measurement of high-frequency signals. Measuring system according to one of the preceding claims, wherein the second field device (11') is designed to determine the first process variable of the measuring medium (2), and wherein the second field device (11') in the line section (3) in relation to the flow direction of the Measuring medium (2) is arranged at a defined distance (ΔL) from the first field device (11). Measuring system according to one of Claims 1 until 4 , wherein the second field device (11 '12) is designed as a flow meter (12) to measure a flow (v) of the measurement medium (2) in the line section (3) as a second process variable. measuring system claim 6 , The flow meter (12) being designed in particular according to the Coriolis or thermal measurement principle in order to determine the flow (v) as a mass flow in the line section (3). Measuring system according to one of the preceding claims, wherein the flow meter (12) is designed to determine the flow (v) in particular magnetic-inductively or by means of ultrasound as a volume flow in the line section (3). Method for detecting a foreign body (4) in a measuring medium (2) flowing through a line section (3) by means of the measuring system (1) according to one of the preceding claims, comprising the following method steps: - Determination of a first measured value (m1) of a first process variable of the measuring medium (2) in the line section (3) using the first field device (11), - Measurement of a second measured value (m1', m2) of the first process variable or a second process variable of the measuring medium (2) in the line section (3) by means of the second field device (11', 12), and - Detection of any foreign body (4) based on the first measured value (m1) and based on the second measured value (m1', m2).

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