EP2718703A1 - Impedance method and arrangement for determining the composition of a multiphase mixture - Google Patents

Abstract

The invention relates to a method and an arrangement for determining the composition of a multiphase mixture (MG), the multiphase mixture (MG) having at least three phases, in particular mineral oil, water, sand and/or sludge. The multiphase mixture (MG) is conveyed away or led from a delivery point, for example, in a through-flow device (DF), in particular a pipeline. At least two electrodes (E1, E2) for the capacitive management of an impedance (Zx) of the multiphase mixture (MG) are fitted to the through-flow device (DF) so as to be insulated electrically from the multiphase mixture (MG), and a changing electric voltage having a defined amplitude is applied to the multiphase mixture (MG) by a voltage source (VQ), wherein a frequency of said voltage can be adjusted. Then, with the aid of a reference impedance (Zref), a capacitive measurement of the impedance (Zx) of the multiphase mixture (MG) is carried out (2) via the electrodes (E1, E2). By using a measuring unit (ME), a variation in the impedance that depends on a frequency is then determined and impedance spectra are derived (3) from the variation in the impedance (Zx). Then, by means of an evaluation unit (AW), via an evaluation of the impedance spectra, for example by using partial least squares regression, proportions by volume of the respective phase in the multiphase mixture (MG) are derived (4). The method and the associated arrangement have the advantage in particular that interference caused by electrochemical reactions between electrodes (E1, E2) and multiphase mixture (MG) is prevented and therefore the measurement is very robust and can be used flexibly.

Description

 description

IMPEDANCE METHOD AND ARRANGEMENT FOR BES IMMUNIZING THE COMPOSITION OF A MULTI-PHASE MIXTURE

Technical area

The invention relates to a method and an arrangement for determining a composition of a multiphase mixture, wherein the multiphase mixture comprises at least three phases, into ^¬ particular oil, water, sand and / or sludge, comprising. In this case, the multiphase mixture is conveyed away or discharged in a flow-through device, in particular a pipeline, for example, from a delivery point.

State of the art

In numerous industrial processes, such as e.g. in the production of crude oil or crude oil, so-called multi or multi-phase mixtures are involved, through which, for example, flow-through devices (for example pipes, pipes, etc.) are flowed through. The problem often arises that not only a total mass flow, but also a ratio and / or proportions of the different phases in the multiphase mixture for an efficient flow of

 industrial process are important. A knowledge of

Mass flow and the ratio of unter ^¬ different phases are important for example for billing, for a control of the multiphase pump and in particular for setting a delivery rate (eg in oil production) and for quality monitoring.

In oil production, for example, the extracted crude oil is often mixed with water and natural gas and contaminated by sand or mud. For efficient oil production, however, it is desirable to have a share of

keep unwanted substances (eg water, sand, mud, etc.) as low as possible. This is tried by a to achieve suitable litigation. For this, however, it is necessary to know a composition of the promoted multiphase mixture. This was - especially for the

Earth extraction in the offshore sector - since around 1980 a so-called multiphase flowmeter has been developed. Such devices are capable of producing two or three phases of a multiphase mixture - such as e.g. Oil, water and gas - to capture.

A multiphase flowmeter is a device used primarily in the oil and gas industry, and which measures and monitors flow rates of individual phases (eg, oil, water, gas) without prior separation of phases during the oil production or production process can be. In this method of phase detection of multi-phase mixtures, for example, a distinction can be made between local measurement and a so-called cross-sectional measurement.

In the local measurement, e.g. needle-shaped sensors introduced into the multiphase mixture. On the basis of the different physical properties determined by the sensors, it can then be detected in which phase of the multiphase mixture the sensor is currently located. In this case, different sensor principles can be used - such. Conductivity, capacitance, thermal diffusivity - or, for example, electrochemical and / or optical sensors are used to measure and detect each phase. Such a multi-phase flowmeter, in which one or more optical sensors are used, for example, from the years

2005-2008 brochure "Optical Multiphase Flowmeter" by Weatherford International Ltd. at http://www.heatherford.com/weatherford/groups/web/documents/weatherfordep/WFT020125.pdf.

In the cross-section measurement is either a reduction of radioactive or by X-ray radiation or a measurement of impedance or the electrical conductivity of the Mixture used to the respective phases or their

Determine shares. From the document "Vx Technology - Multiphase flow rate measurements without fluid separation" by Schlumberger, dated September 2007, which is published eg at http://www.slb.com/resources/otherresources/ brochures / testing / multiphase_vx_technology_brochure. is a method or a multi-phase flowmeter known in which radioactive radiation is used for phase determination.

However, the measuring methods for determining proportions of the respective phases of a multiphase mixture have the

Disadvantage that they often have a complex structure on ^¬ . Therefore, they are often too expensive for practical use and often only suitable for testing samples.

Furthermore, the cited, known multiphase flowmeters are usually limited to one measurement or determination of the phases of petroleum, water and gas and can therefore difficult or even impossible to detect contamination by sand and / or sludge in a multiphase mixture.

The document US 2006/0265150 AI a method and an apparatus for characterizing a multiphase fluid mixture - especially of two-phase emulsion mixture (eg oil-water emulsion, sugar-water mixtures, etc.) - known by which interesting Parameters of the multiphase fluid mixture such as a relationship of the phases of

Mixture, particle sizes of particles dissolved in the mixture and / or characteristics of a bubble foam phase, etc. are detected and / or measured by means of sensors. In this case, the so-called electrical impedance ^¬ spectroscopy is used in combination with other sensors for a measurement of eg temperature, pH, etc. of the mixture as a measuring method. The sensors for the electrical impedance spectroscopy are in contact with the multiphase fluid mixture for the measurement. Impedances of the multiphase fluid mixture are determined over a frequency range of 0.1 Hz up to 1 MHz and then in a computing unit with the aid of derives the corresponding desired parameters from a mathematical model.

However, the method disclosed in document US 2006/0265150 A1 as well as the associated device have the disadvantage that the sensors for the impedance measurement are in direct contact with the multiphase fluid mixture. As a result, disturbances due to electrochemical reactions between a sensor surface and the multiphase fluid mixture can occur and influence the measurement results or the measured impedance values. This may result in errors in the derived parameters (e.g., ratio of phases, etc.), which may be caused, for example, by additional

Measurements elicited and by consuming and costly post-processing and / or additions to the mathematical

Model must be compensated for evaluation.

The method disclosed in document US 2006/0265150 A1 also has disadvantages in the case of use in a so-called flowmeter, in particular in oil production and / or processing, since it is possible to determine a composition of a multiphase mixture due to the low frequency range of .mu.m used for the measurement 0.1 Hz up to 1MHz can take a relatively long time. For example, a recording of a measuring point for the impedance spectrum at a frequency of 0.1 Hz takes about 5 to 10 seconds, and the recording of an entire spectrum may take, for example, one minute or more. Thus it is difficult to not respond to rapid changes in the composition (eg, transitions between phases which can change rapidly, impurities, etc.) up, which, where appropriate, together ^¬ setting the multiphase mixture can be determined only in error. In addition, impurities due to sand and / or sludge or their proportion in a multiphase mixture can likewise not be detected with the method described in document US 2006/0265150 A1. Presentation of the invention

The invention is therefore based on the object of specifying a method and an arrangement, by means of which a composition of a multiphase mixture can be determined without faulty measurements and / or trouble-free even with rapid changes in a simple and cost-effective manner.

According to the invention, the object is achieved by a method and an arrangement of the type mentioned by the in the independent claims 1 and 9

described features. Advantageous embodiments of the method or the arrangement are in the dependent

Claims cited.

According to the method of the invention, it is provided that electrodes are mounted in an electrically insulated manner from the multiphase mixture at a flow-through device for the multiphase mixture. On the multiphase mixture is then a

changing electrical voltage, in particular AC voltage applied with a defined amplitude, wherein the frequency can be adjusted. Then it will be over the

Electrodes performed a capacitive measurement of an impedance of the multiphase mixture and determines a dependent of a frequency waveform of the impedance using a measuring unit. Impedance spectra are then determined from the impedance curve determined with the aid of the measuring unit, and volume fractions of the respective phases in the multiphase mixture are derived by an evaluation unit via an evaluation of the impedance spectra.

The main aspect of the proposed solution according to the invention is that it can be ensured by the insulated electrodes, that a measurement, in particular the impedance, not by electrochemical reactions to the

Electrodes are disturbed. The measurement of the impedance of the multiphase mixture is thus more robust and stable in a simple and cost-effective manner. In a determination of a Frequency-dependent impedance curve or the impedance spectra and in an evaluation of the measurement results or impedance spectra are therefore no complex and complex

Corrections, etc. of any disturbances. The inventive method provides - especially for more than two phases in a multi-phase mixture as well as for shares of sand and / or sludge volume fraction with a relatively good accuracy (about 5 to 10%). It is advantageous if derived impedance spectra

and / or determined volume fractions of the respective phase of the multiphase mixture are output and displayed via an output unit. Thus, measured and / or determined values - such as e.g. Impedance curves of the respective phases, impedance spectra, volume fractions, etc. - are displayed in a simple and rapid manner and it can be easily read a composition or a change in the composition of the multiphase mixture. It is advantageous if the electrodes on the outside of a

Outside wall of the flow device are attached. In this simple way, the electrodes are electrically isolated from the multiphase mixture by the outer wall of the flow device. It will be so easy

prevents electrochemical interference during the measurement.

 In addition, the electrodes can be easily mounted and removed in this way if necessary, e.g. At another point of the flow device, a measurement should be made.

In the case of more complex measuring locations or if a position for an impedance measurement of a multiphase mixture is difficult or hardly accessible from the outside for the attachment of electrodes, it is alternatively possible to use the electrodes

electrically isolated from the multiphase mixture within the

Flow device to install. By appropriate attachment and isolation of the multiphase mixture are

also electrochemical reactions at the electrodes, which lead to errors and errors in the impedance measurement prevented.

Ideally, the evaluation of the impedance spectra with the so-called partial least squares regression - PLS - performed. The PLS is a static method of multivariate analysis, which is described e.g. is used to find relations between two matrices - e.g. a latent one

Variable approach to model covariance structures in matrix spaces. The PLS is also used, for example, in so-called Near Infrared Spectroscopy (NIR Spectroscopy) for evaluation purposes and also supplies in the

Evaluation of the impedance spectra a determination of the volume fractions of the respective phases in a multiphase mixture with relatively good accuracy of about 5 to 10%.

For a determination of the composition of a multiphase mixture, it is advantageous if an impedance spectrum in a frequency range from 10 kHz to 20 MHz is recorded with the electrodes. Practical tests of the determination of volume fractions with multiphase mixtures having at least three phases, in particular a mixture of oil, water and sand or sludge, have shown that in this frequency range a measurement of the impedance with electrically insulated electrodes, in particular attached to the outer wall of the flow-through device, is good Values for determining the volume fraction of the respective phases as well as for transitions between the phases can be achieved. The error and interference susceptibility of the method according to the invention is rather low in this frequency range. In addition, relatively fast measurements can be made in the frequency range from 10 kHz to 20 MHz, since this frequency range is sufficiently high to be able to record several impedance spectra per second. This is particularly advantageous when using the invention in a multi-phase flowmeter.

An expedient development of the invention

Method provides that in the capacitive measurement of the Impedance of the multi-phase mixture is a reference impedance, in particular ^¬ a capacity is used. Because when applying an AC voltage or an associated

electrically variable field, the multiphase mixture acts as a dielectric, in which as a result of

Movement of the dipoles (= dielectric relaxation) and charge ^¬ carriers caused by the applied alternating field, an impedance - in particular a capacity - indirectly via voltage drops can be measured. In order to be able to determine this impedance, which depending on the phase, phase transition, etc. of the multiphase mixture due to different dielectric constants, conductivity, etc. dependent on a frequency course, is in addition to the applied

Voltage and the voltage drop measured across the electrodes requires a third voltage value. This reference is determined by means of the reference impedance ^¬ value which ideally is designed as a capacitance, since the by the used in the inventive process mounting

Electrodes a frequency-dependent proportion of the measured

Impedance of multiphase mixture with these (isolated)

Electrodes mainly has a capacitive value.

Furthermore, it is recommended if as electrodes

so-called cross-sectional sensors are used because

Cross-section sensors can be mounted in a simple manner - in particular on outer walls of flow devices for measuring an impedance of a multi-phase mixture.

The solution of the stated object is also achieved by an arrangement of the type specified for carrying out the method according to the invention, which in addition to a

Flow device for the multiphase mixture further at least two electrodes for capacitive measurement of a

Impedance of the multi-phase mixture, which are electrically isolated from the multiphase mixture attached to the flow device. In addition, the arrangement according to the invention comprises a voltage source via which a

changing voltage, in particular AC voltage, with defined amplitude and adjustable frequency can be applied to the multiphase mixture, a reference impedance, in particular capacitance, a measuring unit for determining a frequency-dependent course of the measured

Impedance and determining the associated impedance spectra and an evaluation unit for determining volume fractions of the respective phase in the multiphase mixture.

The main aspect of the arrangement proposed according to the invention is, above all, that through the use of

electrically insulated electrodes is ensured that a measurement of the impedance - by means of a voltage source and a reference impedance, for example by means of

so-called IU method in which on the basis of three known voltage drops (applied AC voltage, voltage drop at the reference impedance and measured voltage drop across the multiphase mixture) an impedance is indirectly determined - is not disturbed by electrochemical reactions at the electrodes. The inventive arrangement thus provides a simple and inexpensive way a robust and stable measurement of the impedance of the multiphase mixture.

The measuring unit of the arrangement according to the invention then determines a frequency-dependent impedance profile and from this the corresponding impedance spectra in the selected

Frequency range (e.g., 10kHz to 20MHz). Of the

Frequency range is chosen such that it is sufficiently high to minimize influence of the electrode insulation, but that it is located in a range in which it is still possible to measure well with analog components (e.g., capacitors, etc.). In addition, in the selected frequency range, measurements of impedance spectra can be made rapidly - i. several spectra per second - recorded. When measuring the impedance or the

Impedance spectra, for example, the so-called

applied dielectric impedance spectroscopy, with no correction carried out or disturbances and errors by electrochemical reactions are to be considered at the electrodes.

In an evaluation unit, the volume fractions of the respective phases are then determined on the basis of the impedance spectra, in particular also fractions for sand and / or sludge in a, e.g. Oil-water mixture - for example, by means of PLS - derived. With its simple design and ease of use, the arrangement is inexpensive and simply practical - e.g. in petroleum extraction and processing - can be used, e.g. Volume fraction of more than two phases i to determine a mixture. Thus, the arrangement according to the invention and thus also the method according to the invention can be applied very simply - also on account of the selected frequency range - in a so-called multiphase flowmeter.

It is advantageous if an output unit is provided for outputting and displaying the impedance spectra and the determined volume fractions of the respective phase in the multiphase mixture. Via the output unit can quickly and efficiently, the determined values - such as impedance profiles of the respective phases, impedance spectra, by volume, etc are issued, for example, as a numerical value or in the form of curves ^¬ gradients.

Brief description of the drawing

The invention will now be described by way of example with reference to the accompanying drawings. Show it:

Figure 1: by way of example and schematically a flow of the inventive method for determining a composition of a multi-phase mixture and the associated

Arrangement for carrying out this method

FIG. 2 shows, in an exemplary and schematic way, a structure for measuring / determining an impedance of the multiphase mixture with electrodes and measuring unit. Embodiment of the invention

FIG. 1 shows, by way of example and in a schematic way, the arrangement according to the invention and a sequence of the method according to the invention for determining a composition of a multiphase mixture MG which can be composed, for example, of a mixture of crude oil, water, sand and / or sludge. From the multiphase mixture MG is a flow device DF such. a pipe or a pipe in an exemplary direction R flowed through.

There are at least two electrodes El, E2 attached to an outer wall of the flow device DF and thus electrically isolated from the multiphase mixture MG. These electrodes El, E2 can be designed as so-called cross-sectional sensors. Alternatively, however, it is also conceivable that the electrodes E1, E2 are designed as insulated electrodes E1, E2 and are located within-eg on an inner wall-the flow-through ^device DF.

With the electrodes El, E2 a capacitive measurement of an impedance Zx of the multiphase mixture MG is carried out. For this purpose, in a first method step 1 via a voltage source VQ - as shown in Figure 2 - a changing

electrical voltage with a defined amplitude applied to the multi ^¬ phase mixture MG. In the multiphase mixture MG, a movement of the charge carriers or dipoles is caused by the changing voltage or the changing electric field, which is also referred to as electrical relaxation. Due to the different dielectric constant ^¬ or the different conductivity of the respective phases of the multiphase mixture and the MG

Different relaxation processes at the phase boundaries can then be measured in a second method step 2, an impedance Zx of the multiphase mixture via the electrodes El, E2. This impedance Zx has a course which depends on a frequency and thereby Conclusions on a composition of the multiphase mixture MG allowed.

A measurement of the impedance Zx takes place - as shown by way of example in FIG. 2 - for example according to the so-called IU method with the aid of a reference impedance Zref, which is e.g. can be designed as a capacity. As a component for the construction of the corresponding measuring circuit can do so

Capacitor can be used. The voltage from the source VQ, which is impressed on the multiphase mixture MG, causes on the one hand a voltage drop Vref at the reference impedance Zref and on the other hand a voltage drop VZx at the

Impedance Zx of the multiphase mixture MG. The voltage drop VZx is then measured via the electrodes E1, E2. On the basis of the three known voltage values VQ, Vref and VZx as well as the known reference impedance Zref, the unknown impedance Zx of the multiphase mixture MG can then be determined, for example with the aid of the measuring unit ME. The electrodes E1, E2 are-as shown schematically in FIG. 1-connected to a measuring unit ME, wherein the measuring unit ME has the structure shown schematically and exemplarily in FIG. 2 for determining the impedance Zx, in particular the source VQ for generating the changing electrical voltage with defined amplitude and adjustable frequency or the changing electric field and the reference impedance Zref may include.

In a third method step 3 then a frequency dependent course of the impedance Zx of the multi-phase mixture MG, which by capacitive measurement with the

Electrodes El, E2 has been determined, for example, in a frequency range of 10 kHz to 20 MHz determined. For this course then in the measuring unit ME impedance spectra - for example, by so-called dielectric impedance spectroscopy ^¬ - derived. The measuring unit ME is connected to an evaluation unit AW, which can be designed, for example, as a PC or as a microcontroller, and data (eg impedance spectra, etc.) is generated between the measuring unit and the evaluation unit.

replaced.

In a fourth method step 4, the data supplied by the measuring unit ME, such as e.g. the impedance spectra to the measured impedance Zx of the multiphase mixture MG from the evaluation unit e.g. with the help of the Partial Least

Squares regression (PLS) evaluated. In this case, from the impedance spectra volume fractions of the respective phase in

Multi-phase mixture can be derived MG. To the evaluation unit AW is still an output unit

AE connected via which in a fifth method step 5 result data can be output and / or displayed. In this example, the Zx of the respective phases in the form of curves or in the form of numerical values displayed by the frequency difference ^¬ union profiles of the impedances. In addition, also from the

Volume fractions of the respective phases of the multi-phase mixture MG derived from different impedance spectra - e.g. in tabular form - are output, the evaluation with PLS shows that the volume fractions of the phases can be determined with an accuracy of about 5 to 10% and thus is relatively robust.

The inventive method and the arrangement are also against electrochemical reactions and consequent disturbances on the electrodes El, E2 by interaction with the multiphase mixture MG - due to the electrical insulation or electrically isolated attachment of the

Electrodes El, E2 - insensitive. In addition, the

Arrangement and thus the method in a simple way

Multiphase flowmeter can be applied.

Claims

 claims

1. A method for determining a composition of a

 Multi-phase mixture (MG), wherein the multi-phase mixture (MG), which consists of at least three phases, in particular

Petroleum, water, sand and / or mud, is one

 Flow device (DF), in particular a pipe, is flowed through, characterized in that ss electrodes (El, E2) are electrically isolated from the multiphase mixture (MG) attached to the flow device (DF), that on the multiphase mixture (MG) a changing electrical voltage (VQ) with

 is applied (1), that then on the electrodes (El, E2) a capacitive measurement of an impedance of the multiphase mixture (MG) is carried out (2) that a frequency-dependent course of the impedance (Zx) and from the course of the impedance (Zx) impedance spectra are determined (3), and that then by means of an evaluation unit (AW) via an evaluation of the impedance spectra volume fractions of the respective phase in the multi-phase mixture (MG) are derived (4).

2. The method according to claim 1, characterized in that derived impedance spectra and / or determined

Volume components of the respective phase in the multiphase mixture (MG) via an output unit (AE) output and

 be displayed (5). 3. The method according to any one of claims 1 to 2, characterized

 in that the electrodes (El, E2) are mounted on the outside on an outer wall of the flow-through device (DF). 4. The method according to any one of claims 1 to 2, characterized

in that the electrodes (El, E2) are mounted electrically isolated from the multiphase mixture (MG) within the flow-through device (DF). Method according to one of claims 1 to 4, characterized in that the evaluation of the impedance ^¬ spectrums with the so-called Partial Least Square

Regression - PLS for short - is carried out (4).

Method according to one of claims 1 to 5, characterized in that the electrodes (El, E2) an impedance spectrum in a frequency range of 10 kHz to 20 MHz is received.

Method according to one of claims 1 to 6, characterized in that, for the capacitive measurement of the impedance (Zx) of the multiphase mixture (MG) ^¬ a reference impedance (Zref), in particular a capacitor, is used.

Method according to one of claims 1 to 7, characterized in that as electrodes (El, E2) so-called cross-sectional sensors are used.

Arrangement for carrying out a method according to claims 1 to 9, wherein a flow device (DF), in particular a pipeline, for a multi-phase mixture (MG), which consists of at least three phases, in ^¬ particular petroleum, water, sand and / or mud , is provided, characterized in that are further provided:

 - At least two electrodes (El, E2) for capacitive

Measuring an impedance (Zx) of the multiphase mixture (MG), which are electrically isolated from the multiphase mixture (MG) at the flow-through device (DF),

 a voltage source (VQ) for applying a changing voltage, in particular alternating voltage, with a defined amplitude and adjustable frequency,

 a reference impedance (Zref), in particular a

Capacity,

a measurement unit (ME) for determining one of Frequency-dependent course of the measured impedance (Zx) and for determining the associated impedance spectra, - an evaluation unit (AE) for determining volume fractions of the respective phase in the multiphase mixture (MG).

10. Arrangement according to claim 9, characterized in that ss for an output and display derived

 Impedanzspektren and / or determined volume fractions of the respective phase in the multiphase mixture (MG) a

 Output unit (AE) is provided.