DE102013103518A1 - Prefabricated in-line measuring device - Google Patents

Abstract

Prefabricated in-line measuring device (2) comprising a first measuring sensor (4) for the spectrometric determination of the concentration of at least one component of a measuring medium by means of an optical measuring principle, the first measuring sensor being integrated into a measuring tube, which comprises a pipe section, which pipe section a piping system can be connected.

Description

The invention relates to a prefabricated in-line measuring device.

To determine the composition of measuring substances, such as gases, it has become known from the prior art to use optical measuring methods, such as, for example, the so-called Tunable Diode Laser Absorption Spectroscopy. A device intended for this purpose is known from the published patent application US 2008/0288182 A1 known. There it is proposed to remove gas from a pipeline and supply it to a sensor for determining the concentration of a component of the withdrawn gas.

Furthermore, in-line measuring devices for flow measurement, in which the sensor is integrated in a measuring tube or in which the measuring tube is part of the flow meter, are from the prior art, for example, from the WO 2006074850 A1 and the DE 10 2011 006 971 A1 and become known from a variety of other publications.

A flowmeter includes in such in-line designs at least one sensor, which is integrated into the measuring tube, so that for commissioning of the in-line measuring device, the measuring tube must be installed only in an existing pipeline system. This is often done by the measuring tube is clamped via corresponding process connections zw two pipe sections.

Due to the insufficient knowledge of the composition of a medium or the unknown flow profile, however, an inaccurate determination of the desired measurement is possible. On the one hand, this applies to the flow measurement, in which, for example, the flow rate, eg. Based on the flow rate of the medium, the volume flow and / or the mass flow of the medium is determined, on the other hand result, in particular flow-dependent, inaccuracies in the determination of another measure of the Medium such as the concentration of a component of the medium.

In addition, it is problematic and possibly expensive to use several sensors, e.g. are integrated into different measuring instruments, to install in a pipeline and to match these, in particular to calibrate. Therefore, the retrofitting of a system with another sensor often requires a new calibration and thus a possibly longer system downtime.

In addition, the subsequent installation of a sensor, in particular a sensor based on an optical measuring principle or another sensor for determining the concentration of a component of the medium in an existing piping system often requires not only a shutdown of the system but also a calibration on site and possibly the use thereof required fluids, such as, for example, certain liquids or gases.

It is therefore an object of the present invention to overcome the disadvantages of the prior art.

The object is achieved by a prefabricated in-line measuring device comprising a first sensor for, preferably spectrometrically, determining the concentration of at least one component of a medium by means of an optical measuring principle, wherein the first sensor is integrated into a measuring tube which comprises a pipe section, which pipe section can be connected to a pipeline system.

The proposed in-line measuring device is therefore assembled at the factory, for example by the manufacturer of the measuring device, so that only the measuring tube of the measuring device has to be inserted into an already existing pipeline system. Furthermore, a calibration of the meter can be made at the factory. The corresponding calibration data can be stored in the meter. The measuring device can therefore already be put into a system, in particular at a measuring point provided for it, and put into operation particularly easily.

The proposed prefabricated in-line measuring device is preferably a measuring device for gas analysis, wherein the concentration of at least one component of the gas is determined by means of a spectrometric method. The constituents of the gas or the gas mixture can thus be determined. Thus, in one embodiment of the invention, a prefabricated in-line gas spectrometer is proposed.

The measuring tube or the pipe section is particularly preferably a pipe section in the form of a so-called spoolpiece, also referred to as a pipe spool, which has at its ends connecting means, such as flanges or stops, for connecting the pipe section to serve a piping system. The problem of aligning the first sensor and / or the orientation of the measuring path between a transmitting and / or receiving unit of the first sensor can thus be eliminated, since the sensor together with Measuring device is prefabricated. For commissioning, the prefabricated measuring device now only has to be connected to a piping system.

In one embodiment, the prefabricated in-line measuring device comprises a second sensor, which is integrated in the measuring tube, and which serves to determine a flow rate, a volume and / or mass flow. The first and the second sensor can thus be coordinated and / or calibrated together.

In one embodiment, the prefabricated in-line measuring device comprises a pipeline section, which serves to guide the medium, in which pipeline section a window is provided, which is transparent to wavelengths in the optical region, and which window serves to generate an optical measurement signal, the Determining the concentration of the at least one component of the medium is used to couple into the medium. It can also be provided two windows, one for a transmitting unit, the other for a receiver unit. Instead of a second window, a reflector such as, for example, a mirror for the optical measurement signal of the first sensor can be used.

By way of example, the optical measuring signal can be conducted through the measuring tube and the medium being conveyed therein during operation along a measuring path, preferably a rectilinear measuring path, through the measuring tube. In addition, a receiving unit for receiving the optical signal may be arranged at one end of the measuring path, which receiving unit, for example, via a window integrated into the measuring tube with the lumen of the measuring tube, in which the medium is guided in operation, couple to the optical Receive measurement signal. On the other hand, the measuring path can run through the measuring tube along a metrologically optimized angle. Furthermore, for example, a mirror may be provided which reflects the optical measurement signal back to the transmitter.

In a further embodiment, the at least one window is arranged in alignment with the wall of the measuring tube. Thus, a non-invasive or minimally invasive design can be achieved, so that the medium in the measuring tube is not obstructed when flowing through the measuring tube.

In a further embodiment, the measuring path of the first measuring sensor and the measuring path (s) for the flow measurement are arranged at an angle to one another, so that they do not interfere with one another and the size can be kept as small as possible.

In a further embodiment, the in-line measuring device can be clamped in the course of a pipeline system via a process connection at one end of the pipeline section. For example. For example, flanges may be provided at the two metering tube ends to permit connection to a piping system. From the prior art, designs have become known in which a measuring tube via its ends, are slipped over the example. Sleeve, connected to a piping system.

In another embodiment, the window for coupling the optical signal to the lumen, i. the inner cross section of the pipe section. The window for decoupling the optical measuring signal preferably also adjoins the lumen of the measuring tube.

In a further embodiment, the window has a functionalized surface, wherein adjoining regions of this surface differ from one another with respect to their adsorption behavior. As a result, any condensation of liquid possibly occurring in the measuring tube at the window can be prevented, or the optical path of the optical measuring signal can be kept free of condensate. For example. For example, these areas may be annular so that condensate is always directed outward, i. is transported away in the direction of the wall of the measuring tube.

The window is preferably part of a screw-in sensor. The first sensor, which as already mentioned is an optical sensor, is screwed, for example, into a provided opening of the measuring tube, so that it couples with the lumen. The window can be integrated in the optical sensor. Alternatively, the window is integrated into the wall of the measuring tube and the sensor, i. the optical transmitting and / or receiving unit can be coupled to the window.

In a further embodiment, the in-line measuring device has a cleaning operation in which the window can be heated. For example. Heating wires can be used, which serve to free the window in a cleaning operation of a deposit. Alternatively, the temperature of the window can be adapted to that of the medium, so that a condensation of the medium is avoided.

In a further embodiment, the in-line measuring device has a cleaning operation in which the window can be set into mechanical oscillation.

In a further embodiment, the in-line measuring device comprises a measuring electronics, which for Evaluation, processing and / or measurement data generation, which is used by the first and / or the second sensor recorded measurement signals. The measuring electronics thus serves to process both the signals of the first sensor and the signals of the second sensor. Various modes of operation may also be provided to temporarily process either only the signals of the first sensor or only the signals of the second sensor. In the embodiment of the proposed prefabricated in-line measuring device in which only a first sensor is part of the measuring device, a measuring electronics can also be provided, which then serves to process only the measuring signals of this first sensor.

In a further embodiment, the measuring electronics supplies, on the basis of the measuring signals of the first and second measuring sensors, a value of an energy content of the medium flowing through the pipe section.

In a further embodiment, the measurement signal of the second sensor for determining the flow rate, the volume and / or mass flow is used to correct the measured signal supplied by the first sensor or the corresponding measured value, preferably based on stored data, to the concentration of at least to determine a component, in particular more precisely than in conventional analysis devices of this type.

For example. For example, on the basis of a measured value of the second measuring sensor, at least one measured value of the first measuring sensor can be corrected on the basis of empirical values or calibration values, because e.g. It is known that at a certain flow rate or at a certain mass flow rate, there is a particularly large measurement error or a measurement deviation in a certain direction. For this purpose, for example, a memory unit may be provided, which is integrated into the measuring device or is arranged remotely from the measuring device, but is in communication with the measuring device. In addition or as an alternative, a calculation rule, for example in the form of a correction polynomial, can also be predefined or stored, in which the flow is contained as a variable. Thus, a measured value of the first sensor can be determined based on a measured value of the second sensor.

In a further embodiment, the measured value of the flow rate, of the volume flow and / or of the mass flow, preferably based on stored data, is calculated and / or corrected on the basis of at least one measured signal or measured value of the concentration of at least one component of the medium. For example. can be taken on the basis of data stored in a storage unit data associated with a certain measured concentration of the measured properties. These can then be used to determine or correct the measured value and / or measuring signal of the second measuring sensor. For example. can in the case of a thermal flow sensor on the basis of the supplied from the heatable temperature sensor signal and the measured properties, such as the dynamic viscosity, the thermal conductivity, the thermal conductivity, etc. (which are derived from the determined concentration of at least one component of the medium) the mass flow rate can be determined with improved accuracy.

In another embodiment, the in-line meter includes a flow conditioning device to affect the flow profile of the fluid flowing through the tubing section during operation. This flow conditioning may be located upstream of the first sensor and the second sensor. As a result, constant measuring conditions can be created in the region of the first measuring sensor, which first measuring sensor preferably serves for determining the concentration of at least one component on the basis of an optical measuring principle.

In a further embodiment, the second sensor is a gem. the ultrasonic transducer working.

In a further embodiment, the second sensor is a gem. the measuring principle working with the thermal measuring principle.

In a further embodiment, the first sensor is a gem. the laser anemometric measuring principle (LDA: laser Doppler anemometry) working sensors.

In a further embodiment, the first sensor is a TDLAS. TDLAS stands for tunable diode laser absorption spectroscopy. In a further embodiment, concentration of the components of the medium is determined by evaluating the absorption characteristics when passing through the measuring range of the first sensor. Thereby, the concentrations of all components can be determined, which have a characteristic absorption characteristic in the measuring range of the first sensor.

Advantageously, the use of semiconductor diode lasers proposed here whose wavelength can be adjusted itself in a defined bandwidth, eg by means of temperature change, or can be changed by external measures, for example by means of a MEMS system. As an example, so-called external cavity diode laser, distributed Bragg reflector laser or quantum cascade laser can be mentioned here.

Alternatively, the first sensor can also be a sensor for Raman spectroscopy. Raman spectroscopy can also be used to determine the composition of the medium, ie the concentration of a component of the medium.

The invention will be explained in more detail with reference to the following drawings. It shows:

1 : a schematic representation of an in-line measuring device.

1 shows a schematic representation of a prefabricated in-line measuring device 2 with a sensor 4 in the form of an ultrasound-based flowmeter and a sensor 7 in the form of a measuring sensor based on the measuring principle of laser spectroscopy for determining the concentration of at least one component of a medium flowing through the measuring tube.

The first and the second sensor 4 . 7 are in the measuring tube 1 or its wall integrated. The measuring tube 1 indicates the inclusion of the first and the second sensor 4 . 7 corresponding connections 3 on. For example. can be like in 1 shown the corresponding sensors 4 . 7 in a corresponding connection 3 on the measuring tube 1 be screwed.

The first and the second sensor 4 . 7 are preferably connected to a common signal or data processing unit, not shown, connected, so that the measurement signals or measured values are transferable to this signal or data processing unit and can be processed there alternately or simultaneously. Corresponding connections for signal transmission can be used on the sensors 4 . 7 be provided.

The in-line measuring instrument is assembled at the factory and only has to be integrated into an existing piping system.

By means of the ultrasonic flowmeter 4 Thus, for example, the mean flow velocity of the medium can be determined, for example, by means of the signal or data processing unit.

Furthermore, by the sensor 7 to determine the concentration of at least one component of the medium, the composition of the medium or just the concentration of at least one component can be determined.

Preferably, the volume flow or the (average) flow rate and / or the mass flow and the concentration of the component / components of the medium are measured by means of the sensor 7 determined approximately at the same time as the measurement signal or the measured value of the flow rate or of the volume and / or mass flow through the sensor 4 ,

Thus, for a given through the measuring tube 1 flowing medium both its flow rate or a value derived therefrom or the volume flow and / or the mass flow and its composition, ie composition, are determined - and for exactly a certain amount of the medium, namely the one at the time of measurement is in the measuring tube.

Thus, a highly accurate and adapted to today's needs measurement of the desired measurement is possible because nowadays often media with varying concentration of a component are processed. Such as in the promotion or transport of gases.

Furthermore, it is a further idea of the present invention on the basis of the measuring signals or the measured values of the measuring sensor 7 the one from the sensor 4 to correct the supplied measuring signal / measured value or to use the measuring signal / measured value supplied by the second measuring sensor for calculating the flow velocity, the volume or mass flow.

On the basis of the determined concentration of one or more components of the medium can be determined, for example, in a database or other storage unit associated with this concentration chemical and / or physical properties of the medium. For example. Depending on the composition of the medium to be measured, the thermal conductivity, the viscosity, the density, the thermal conductivity or another variable required for the evaluation and measured value calculation can be determined by calculating these values from the concentration (s) of the components of the medium or from a storage unit be retrieved.

These media properties can then be used to calculate or correct the desired metric.

In addition, it is possible, based on the determined flow measurement signal, such as, for example, the (average) flow rate, the volume flow rate and / or the mass flow rate, the measurement signal / the measured value of the sensor 7 to correct or to use for the calculation of the same. For example. It is known from the prior art that sensors based on an optical measuring principle are subject to measurement value corruption in the case of a moving medium. Due to the combined design of the proposed in-line measuring device 2 can now be based on the flow measurement signal a corresponding correction if necessary, for example. From a certain threshold value of the measured flow done.

Instead of in 1 shown on the ultrasonic measuring principle based sensor 4 can also be based on another measuring principle based sensor 4 be used. For example. a sensor based on the thermal flow measurement principle may be used or a sensor based on the magnetic inductive measurement principle may be used. The use of other not mentioned here sensor is conceivable.

At the sensor 7 it is preferably a sensor, which is based on an optical measuring principle, preferably with a transmitter LD and a receiver PD of an optical measurement signal. The optical measuring signal is along a measuring path, in 1 represented by the dashed line between transmitter LD and receiver PD, between the transmitter LD and the receiver PD at least through a part of the lumen, which is at least partially filled in the Messbetreib of the medium.

In 1 Here is a so-called. Cross duct design shown, in which the optical measurement signal from one side of the measuring tube 1 transferred to the opposite side. However, it is also possible to use a so-called measuring lance. It is also possible to irradiate the measuring tube along a measuring path that is shorter than the diameter of the measuring device.

If the medium is a gas, gas analysis can be performed using multispectral pyroelectric infrared detectors.

Of course, it is also possible that only the sensor based on an optical measuring principle 7 for determining the concentration of the at least one component of the medium is integrated into the measuring tube. The advantages of the invention and the embodiment of in 1 shown embodiment and the associated description then apply accordingly.

LIST OF REFERENCE NUMBERS

1

 Measuring tube / Messrohrwandung

2

 In-line measuring device

3

 Connection for the first or second sensor

4

 second sensor

7

 first sensor

17

 Measuring tube axis

LD

 Sending unit for optical signal

PD

 Receiving unit for optical signal

S

 flow direction

F1

 First window

F2

 Second window

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

• US 2008/0288182 A1 [0002]
• WO 2006074850 A1 [0003]
• DE 102011006971 A1 [0003]

Claims (15)

Prefabricated in-line measuring device ( 2 ) comprising a first sensor ( 4 ), preferably spectrometric, determining the concentration of at least one component of a medium by means of an optical measuring principle, wherein the first sensor is integrated into a measuring tube, which comprises a pipe section, which pipe section can be connected to a pipeline system. Prefabricated in-line measuring device ( 2 ) according to the preceding claim, wherein the prefabricated in-line measuring device comprises a second sensor, which is integrated in the measuring tube, for determining a flow rate, a volume and / or mass flow. Prefabricated in-line measuring device ( 2 ) according to claim 1 or 2, wherein in the pipe section at least one window (F1, F2) is provided, which is transparent to wavelengths in the optical range, and which window (F1, F2) serves to generate an optical measuring signal, which is used to determine the Concentration of the at least one component of the medium is used to couple or decouple into the lumen of the measuring tube, which serves to guide the medium. Prefabricated in-line measuring device ( 2 ) according to one of the preceding claims, wherein the window (F1, F2) is aligned with the wall of the pipe section ( 1 ) is arranged. Prefabricated in-line measuring device ( 2 ) according to one of the preceding claims, wherein the window (F1, F2) for coupling the optical signal into the lumen, ie the inner cross section, of the pipeline section (FIG. 1 ) adjoins. Prefabricated in-line measuring device ( 2 ) according to one of the preceding claims, wherein the window (F1, F2) has a functionalized surface, wherein adjacent regions of the functionalized surface differ from one another with regard to their adsorption behavior. Prefabricated in-line measuring device ( 2 ) according to one of the preceding claims, wherein the in-line measuring device ( 2 ) has a cleaning operation in which the window (F1, F2) is heated. Prefabricated in-line measuring device ( 2 ) according to one of the preceding claims, wherein the in-line measuring device ( 2 ) has a cleaning operation in which the window (F1, F2) is set into mechanical vibration. Prefabricated in-line measuring device ( 2 ) according to one of claims 2 to 8, wherein the in-line measuring device comprises a measuring electronics, for the evaluation, processing and / or measurement data generation, of the first and / or the second sensor ( 4 . 7 ) recorded measurement signals, serves. Prefabricated in-line measuring device ( 2 ) according to one of claims 2 to 9, wherein the measurement signal of the second sensor ( 4 ) or a measured value derived therefrom, which is used by the first sensor ( 7 ), preferably on the basis of stored data, to correct, in order to determine the concentration of the at least one component. Prefabricated in-line measuring device ( 2 ) according to one of claims 2 to 11, wherein based on at least one of the first sensor ( 7 ) measured value of the concentration of at least one component of the medium, the measured value of the flow rate, the volume flow and / or the mass flow, preferably based on stored data, calculated and / or corrected. Prefabricated in-line measuring device ( 2 ) according to one of the preceding claims, wherein the in-line measuring device ( 2 ) includes a flow conditioning device for controlling the flow profile of the pipeline through the pipeline section (FIG. 1 ) to influence flowing medium. Prefabricated in-line measuring device ( 2 ) according to one of the preceding claims, wherein the second sensor ( 4 ) to a gem. the ultrasound principle working sensor or a gem. acting on the thermal measuring principle sensor is. Prefabricated in-line measuring device ( 2 ) according to one of the preceding claims, wherein the first sensor ( 7 ) is a TDLAS or where the first sensor ( 7 ) is a sensor for Raman spectroscopy. Prefabricated in-line measuring device ( 2 ) according to any one of the preceding claims, wherein the concentration of the components of the medium by evaluating the absorption characteristics when passing through the measuring range of the first sensor ( 7 ) is determined.

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