DE102018124069A1 - Magnetic-inductive flowmeter with sensor for recording a further measured variable - Google Patents

Abstract

The invention relates to a magnetic-inductive flowmeter (1) for measuring the flow of a flowing, conductive medium in a pipe section (2) with a sensor (10) arranged in the pipe section (2) for detecting a further measured variable. According to the invention, the magnetic-inductive flowmeter (1) is to be formed in a simple and cost-effective manner such that properties of the flowing medium as well as certain states of the magnetic-inductive flowmeter can be detected at the same time. For this purpose, the sensor (10) is designed as a thermal flow meter, wherein the sensor (10) is connected to the evaluation unit and there its measurement signals with reference data and / or with the measurement signals of the magnetic-inductive flowmeter (1) are compared.

Description

The invention relates to a magnetic-inductive flowmeter for measuring the flow of a flowing, conductive medium in a pipe section according to the preamble of claim 1.

Magnetic-inductive flowmeters whose operation is based on the principle of electromagnetic induction (= Faraday induction) have been known for many years and are widely used in industrial metrology. According to the law of induction, an electric field strength arises perpendicular to the flow direction and perpendicular to the magnetic field in a flowing medium which carries charge carriers and flows through a magnetic field. The law of induction is exploited in magnetic-inductive flowmeters in that by means of a magnetic field generating device, which usually has two energized magnetic coils, a magnetic field is at least partially passed through the measuring tube, wherein the generated magnetic field has at least one component perpendicular to the flow direction runs. Within the magnetic field, each volume element of the flowing medium moving through the magnetic field and having a certain number of charge carriers with the field strength arising in this volume element makes a contribution to a measurement voltage which can be tapped off via the electrodes.

Since the induced voltage tapped off via the electrodes is proportional to the average flow velocity of the medium over the cross section of the measuring tube, the volume flow can be determined directly from the measured voltage for a known diameter of the measuring tube. Prerequisite for the use of a magnetic-inductive flowmeter is only a minimum conductivity of the medium. In addition, it must be ensured that the measuring tube is at least as far filled with the medium that the level of the medium is above the measuring electrodes. However, since measurement errors that are not completely filled can result in a not insignificant measurement error depending on the degree of filling, magnetic-inductive flowmeters are ideally suited primarily for applications in which the measuring tube is completely filled. For this reason, magnetic-inductive flowmeters in practice usually have a measuring device for empty pipe detection, which indicates to the user when the degree of filling has dropped so low that the determined measured value can no longer be determined with the required accuracy. This can for example already be the case with a measuring tube filled to only two thirds, so that the measuring devices used for "empty tube detection" in practice do not generate a signal until the measuring tube is actually "empty". Various solutions are known for detecting incompletely filled measuring tubes. As an example, let's look at the DE 102012015038 B3 and DE 102010001993 A1 referred to the applicant.

Furthermore, deposits can form within the pipeline, which on the one hand influence the flow of the medium and on the other hand are absolutely to be avoided, in particular in hygiene applications. As a result, appropriate cleaning processes are carried out. Since the pipelines are predominantly hermetically sealed to the outside world, there is no possibility of regular inspection during operation as to whether the cleaning inside the piping has been carried out completely and thoroughly. The cleaning process is therefore typically carried out over a time control according to empirical specifications. However, this cleaning process should not take longer than it should be, because during the cleaning, the availability of the entire system is not given, so affects the production process as such.

In addition, there is always the need for the plant operator to monitor certain properties of the medium flowing through the pipeline, since, for example, changes in this respect over a tolerance band can also indicate an error.

The object of the invention is to develop a magnetic-inductive flowmeter in a simple and cost-effective manner, so that at the same time properties of the flowing medium and certain states of the magnetic-inductive flowmeter can be detected.

The object is achieved by a device having the features of claim 1. Advantageous embodiments of the invention are specified in the subclaims.

According to the invention, the magnetic-inductive flowmeter comprises a thermal flow meter, which measures the flow velocity of the medium by means of a calorimetric measuring principle in parallel with the magnetic-inductive measuring principle. Since a thermal flow meter as a mass flow meter based on a different measurement principle, this results in a diverse redundancy measurement. By comparing with the result of the electromagnetic flow measurement, the measuring accuracy of the measuring devices can be checked, but also changes within the pipeline or the medium can be detected.

For example, deposits on the measurement result of the preferably flush-mounted in the wall of the pipe thermal flow meter such that the detected heat dissipation and thus the calculated flow rate - depending on the thickness of the deposit - significantly different from the result of the magnetic-inductive flowmeter differs ,

The same would be noted at an increased viscosity of the medium. Again, the flow velocity in the wall area would decrease, while the magnetic-inductive flow meter volume-based would measure a much larger flow.

Furthermore, the above-mentioned empty pipe detection is to be mentioned as an application. If the thermal flow meter is installed in the wall of the pipe at the top, it would only measure something with a completely filled measuring pipe. A strong formation of bubbles or foaming, which would falsify the measurement results of the magnetic-inductive flowmeter, could thus be recognized because thermally no flow would be measured by the formation of bubbles and foams.

The reverse case, namely, if the thermal flow meter measures a larger flow than the electromagnetic flowmeter would be, for example, if the conductivity of the medium were to decrease. If the conductivity drops below a minimum value, magnetic-inductive flowmeters will no longer be able to deliver reliable measurement results.

The thermal flow meter comprises a heating element and at least one temperature sensor, wherein the heating element is thermally coupled to the flowing medium and thus emits its heating power to the flowing medium. The at least one temperature sensor selectively detects the temperature of the heated medium and / or that of the heating element, which is in each case dependent on the flow velocity. The measuring method known as the calorimetric principle is known in principle.

In addition to the pure redundancy measurement at the flow or flow rate, it is also possible with the thermal flow meter, to close by comparing the current heat dissipation with a reference value to a specific state. For example, when a cleaning operation has been started, the heating element permanently measures its heat dissipation, for example by detecting the electrical power necessary to maintain the heating element at a predetermined, constant temperature. The heat removal is directly influenced by the type and composition of the effluent. If no or too little amount of cleaning fluid flows over the heating element, this results in less heat removal than if cleaning fluid were present in sufficient quantity. Also, a cleaning liquid that is subject to contamination generates a different heat removal than if the running cleaning liquid finds a clean situation.

The inventive design of a magnetic-inductive flowmeter, it is possible with a single measure, namely the provision of a thermal flow meter in the wall of the pipeline, a variety of monitoring, the state of the magnetic-inductive flowmeter itself or certain properties of the measured Medium, perform simultaneously and thus ensure a reliable flow measurement.

The invention will be explained in more detail by means of embodiments with reference to the drawings.

• 1 perspektivische Darstellung eines erfindungsgemäßen Durchflussmessgeräts und
• 2 Schnittdarstellung des Durchflussmessgeräts nach 1.

They show schematically:

• 1 perspective view of a flowmeter according to the invention and
• 2 Sectional view of the flowmeter after 1 ,

In the following description of the preferred embodiments, like reference characters designate like or similar components.

In 1 is a magnetic-inductive flowmeter 1 shown, in addition to a known and therefore not shown here in detail magnetic-inductive measuring unit 3 essentially from a measuring tube 2 , two connection flanges 4 - Here, for better illustration, only a flange 4 is shown - and one in the measuring tube 2 integrated thermal flow meter 10 consists. The two flanges 4 are mainly used to connect the meter 1 to the respective, not shown here pipelines in which the medium to be measured flows.

From the sectional view according to 2 you can see how the thermal flow meter 10 into the measuring tube 2 is integrated. The flow meter is preferred 10 flush with the front of the measuring tube 2 installed so that inside the measuring tube 2 Dead spaces and flow-obstructive resistances are avoided. It includes a heating element 11 , which is heated and gives off its heat to the medium. At the heating element 11 it is about a temperature-dependent resistor which is pin-shaped and protrudes with its tip into the medium. When the heating element 11 is energized - the electrical contact is not shown for purposes of illustration - it is heated and heated the medium in the region of the tip. The thermal flow meter 10 further comprises a temperature element 12 , which determines the temperature of the medium in a non-heated, ie from the heating element 11 uninfluenced area of the medium detected as the reference temperature. The heating element 11 and the temperature sensor 12 are advantageously designed as a Pt element, preferably as Pt100.

The heating element is preferred 11 at the same time a temperature element which is energized by means of a PWM signal and thereby heated in the high phase and recorded in the low phase its temperature profile during the flow-dependent cooling. For detailed information on this measuring principle, refer to the DE102016223294A1 referred to the applicant.

In the present illustration according to 1 is the thermal flow meter 10 at the top and thus at the highest point of the measuring tube 2 , ie starting from the cross section of the measuring tube 2 at 0 °. In this embodiment can easily complete the filling of the measuring tube 2 be determined because the thermal flow meter 10 only then will generate a measuring signal when using the measuring tips 11 . 12 comes in contact with the medium. This contact can of course only take place when the measuring tube 2 completely filled. On the other hand, the thermal flow meter 10 also at any point on the measuring tube 2 be positioned, in particular at the positions 90 °, 180 ° and 270 °, starting from the cross section of the measuring tube 2 , It is also conceivable to use several flow meters 11 provided.

Not shown further is an evaluation unit, in which the respective measurement signals of the magnetic-inductive flowmeter 1 and those of the thermal flow meter 10 with each other or the thermal flow meter 10 be compared with a lookup table.

LIST OF REFERENCE NUMBERS

1

Magnetic-inductive flowmeter

2

measuring tube

3

Magnetic-inductive measuring unit

4

flange

10

thermal flow sensor

11

heating element

12

temperature sensor

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been 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.

Cited patent literature

• DE 102012015038 B3 [0003]
• DE 102010001993 A1 [0003]
• DE 102016223294 A1 [0021]

Claims (3)

Magnetic-inductive flowmeter (1) for measuring the flow of a flowing, conductive medium in a pipe section (2), - with a coil for generating a magnetic field which is perpendicular to the flow direction, - with two contacting the medium measuring electrodes for tapping by the Flow induced induction voltage and - with an evaluation unit for determining the flow rate from the induction voltage, wherein in the pipe section (2) a sensor (10) for detecting a further measured variable is arranged, characterized in that the sensor (10) is designed as a thermal flow meter comprising a heating element (11) and at least one temperature sensor (12), wherein the heating element (11) is thermally coupled to the flowing medium and thus emits its heating power to the flowing medium and the at least one temperature sensor (12) the temperature of the medium and / or that of the heating element (11) detected, the Senso r (10) is connected to the evaluation unit and there its measurement signals with reference data and / or with the measurement signals of the electromagnetic flowmeter (1) are compared to properties of the flowing medium and / or certain states of the magnetic-inductive flowmeter (1) to determine. Magnetic-inductive flowmeter according to Claim 1 , characterized in that the sensor (10) is arranged flush with the front in the measuring tube (2). Magnetic-inductive flowmeter according to one of the preceding claims, characterized in that the heating element (11) is also designed as a temperature sensor and is energized with a square wave signal, so that it acts as a heating element in the high phase and in the low phase as a temperature sensor ,

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