WO2020058134A1 - System and method for measuring a flow property of a fluid in a porous medium with correction - Google Patents

Abstract

The invention relates to a method and a system (1) for measuring at least one flow property of at least one fluid within a porous medium. The measuring system (1) comprising at least one cell (2) containing the porous medium, x-ray radiography means comprising a source (4) and a detector (5), and electrical measuring means (8). This electrical measuring means (8) is connected by at least two electrical connections to each end of the porous medium, and each of the two electrical connections comprises an electrical powering means and a device for measuring the electric intensity. The measuring system (1) comprises control means for simultaneously carrying out radiographs and electrical measurements.

Description

 SYSTEM AND METHOD FOR MEASURING A FLUID FLOW PROPERTY IN A POROUS MEDIUM WITH CORRECTION

Description

 Title of the invention: system and method for measuring a flow property of a fluid in a porous medium with correction

The present invention relates to the field of measurements of flow properties of a fluid in a porous medium, in particular a porous medium originating from an underground formation. The measurements can be used in particular for determining the residual oil saturation of an underground formation, in particular during the exploration and exploitation of oil wells, and particularly for enhanced oil recovery (EOR: de English Enhanced Oil Recovery).

It is estimated today that for all active oil tanks, 60% -65% of the oil in place remains trapped. Different mechanisms are at the origin of this trapping. For example, geological heterogeneity generates an inhomogeneous displacement of the oil across the reservoir. But even on a local scale, the presence of an interfacial tension between water and oil leads to capillary trapping of the oil phase in the center of the pores in the case of rocks wettable with water. This trapping can represent up to 50% of the oil in place. Water-wettable tanks make up roughly half of the world's tanks.

 Consequently, mobilizing the residual oil contained in the matrix under conditions of preferable wettability with water is a real challenge. However, the use of surfactants injected in the aqueous phase can allow a very significant reduction in capillary trapping. Surfactants have the property of being able to significantly lower this tension or even almost cancel it. The use of surfactant additives was successfully tested on sandstones in the 1980s and is experiencing renewed interest. The processes of enhanced recovery of petroleum (hydrocarbons) by injection of surfactant represent a great potential because they make it possible to trap a large quantity of oil blocked in the pores of the rock.

To characterize capillary trapping, it is necessary to carry out measurements of relative properties of the flow of fluids in the porous medium. Currently, the methods used require several weeks to obtain this characterization of the flow of fluids. Indeed, it is currently necessary to prepare samples of rock having a sufficient pore volume so that the fluids produced and collected at the outlet of the porous volume have a sufficient volume to characterize the properties of the medium (typically several milliliters). Thus, typical sample sizes are on the order of 5 cm in diameter and 10 cm in length. The samples are then initially saturated with water, then drained with oil, and finally swept with water to obtain the residual oil saturation. Then an injection of a volume of an ASP formulation (ASP for Alkaline, Surfactant, Polymer) is carried out and is followed by a final sequence of sweeping with water. At the end of the sequence, the residual oil saturation is deducted from the total volume of oil produced at the outlet of the porous medium.

 Furthermore, in other technical fields, it may be advantageous to rapidly characterize the flow of a fluid within a porous medium, in particular a porous medium formed by a polymer.

 Patent application FR 3 047 315 (WO 17 129 312) relates to a system and a method for measuring the flow properties of a fluid in a porous medium, the principle of which is based on X-ray radiography. This method serves in particular to determine the saturation of a fluid from radiographs generated at regular time intervals. The property of attenuation of the rays is expressed in gray levels on the images of radiographies and it depends in particular on the thickness and the coefficient of attenuation of the various materials crossed by the X-rays. However, this method generates a drift of the levels of gray, the drift being essentially linked to temperature variations affecting the detector's efficiency. This method requires corrections over time, to overcome the drift. By using radiographs, knowing the gray levels of two identical saturation states, states obtained spaced over time, allows the determination of a correction factor. However, it turns out that, in some cases, it is not possible to obtain this knowledge of the gray levels of two identical states of saturation, states obtained in a spaced manner over time. The correction is then approximate and the results which result therefrom then lose precision / reliability.

To overcome the aforementioned drawback, the invention relates to a system for measuring at least one flow property of at least one fluid within a porous medium. The measurement system comprises at least one cell containing the porous medium, means for injecting fluid (s) into the cell, X-ray radiography means comprising a source and a detector, and an electrical measurement means. The electrical measurement means is connected by at least two electrical connections at each end of the porous medium and each of these two electrical connections comprises an electrical tensioning means and a device for measuring electrical intensity. In addition, the measurement comprises control means for simultaneously carrying out radiographies and electrical measurements.

 The invention also relates to a measurement method associated with the aforementioned system.

The method and the system according to the invention

 The invention relates to a system for measuring at least one flow property of at least one fluid within a porous medium, said measuring system comprising at least one cell containing said porous medium, injection means. of said fluid in said cell, and at least one X-ray radiography means comprising a source and a detector, characterized in that the measurement system comprises an electrical measurement means, said electrical measurement means being connected by at least two connections electrical at each end of said porous medium, each of said two electrical connections comprising an electrical tensioning means and a device for measuring the intensity of the electric current and in that the measuring system comprises control means for simultaneously carrying out x-rays by said X-ray radiography means and electrical measurements by said intensity measurement device electric current.

According to one embodiment, said injection means comprise a plurality of fluids to be injected into said cell, simultaneously or sequentially.

 Advantageously, the fluids of said plurality of fluids have different electrical conductivities.

According to a variant, said measurement system comprises means for controlling said injection means.

According to one implementation, said measurement system includes means for analyzing said radiographies obtained by said detector.

Advantageously, said measurement system comprises post-processing means both for the analysis of said radiographs obtained by said detector and for the analysis of said electrical measurements obtained by said device for measuring the intensity of the electric current.

Preferably, the post-processing means is configured to correct said radiographs from said electrical measurements. According to one embodiment of the measurement system, said cell has a substantially cylindrical shape.

 Preferably, the diameter of said cell is substantially between 2 mm and 20 mm, preferably between 5 mm and 10 mm.

 Even more preferably, the height of said cell is substantially between 2 mm and 5 cm, preferably between 5 mm and 2 cm.

According to an advantageous embodiment, said system is suitable for blocking the flow of an aqueous fluid and / or of an oil in the porous medium.

 Preferably, said system is suitable for blocking the flow of an aqueous fluid and / or of an oil in the porous medium, said aqueous fluid comprising at least one additive, preferably a surfactant.

The invention also relates to a method for measuring at least one flow property of at least one fluid within a porous medium, in which the following steps are carried out using the measuring system according to one of the preceding claims: a) X-ray radiography of the porous medium is carried out simultaneously with an electrical measurement of the porous medium;

 b) Analyzing said electrical measurement and said radiography to determine said at least one flow property.

According to an implementation of the method, for the analysis step, electrical measurement is used to correct the radiography in the following manner:

 i. Measurement points are determined on said electrical measurement, said measurement points corresponding to times for which electrical resistivity values, obtained after the same injection conditions, are identical; ii. The said radiographs are corrected for a time drift using the said measurement points.

Advantageously, said same injection conditions include the same injection sequence of one or more fluids and the same distribution of said fluids in said porous medium. According to one embodiment, said flow properties are chosen from the average saturation of said fluid, and / or the saturation profile of said fluid and / or the electrical resistivity of said porous medium.

Advantageously, a plurality of radiographies and electrical measurements are carried out at regular intervals, preferably at intervals of between 0.1 and 5 seconds.

Advantageously, a fluid is injected into the porous medium.

 Preferably, the injection of the fluid into the porous medium is controlled in real time during the measurements.

 Brief presentation of the figures

 Other characteristics and advantages of the method and of the system according to the invention will appear on reading the description below of nonlimiting examples of embodiments, with reference to the appended figures and described below.

 [Fig 1] illustrates, schematically and without limitation, an embodiment of the system according to the invention.

 [Fig 2] illustrates, schematically and without limitation, an embodiment of the electrical measurement of the system according to the invention.

 [Fig 3] illustrates, schematically and without limitation, an example of correction of radiographs by the use of electrical measurement, electrical measurements and radiographs being taken simultaneously, according to the invention.

 [Fig 4] illustrates, schematically and without limitation, the gain in precision on the radiographs thanks to the method and the system according to the invention.

Detailed description of the invention

The invention relates to a system for measuring at least one flow property of at least one fluid within a porous medium (the porous medium being for example an extract from an oil reservoir such as a rock or a polymer ). The measurement system comprises at least one cell containing the porous medium, means for injecting the fluid into the cell, and at least one X-ray radiography means comprising a source and a detector. In addition, the measurement system also includes an electrical measurement means, connected by at least two electrical connections to each end of the porous medium (via the cell). An electrical measuring means comprises an electrical tensioning means and a device for measuring the intensity of the electric current. The electrical tensioning means is connected at different ends (from preferably two different ends, for example, two longitudinal ends) of the porous medium by electrical connections. In addition, the device for measuring the intensity of the electric current is connected to different ends (preferably two different ends, for example, two longitudinal ends) of the porous medium by electrical connections which may be the same as those connecting the porous medium by means of electrical tensioning, or else be other electrical connections than those connecting the porous medium by means of electrical tensioning. Advantageously, each of the at least two electrical connections is connected to each end of the porous medium and at least two of said at least two electrical connections are connected to two different ends of the porous medium, thus making it possible to measure the voltage and / or the intensity of the electrical current across the porous medium and / or imposing a voltage or current across the porous medium, the ends then serving as electrical terminals. When the porous medium has a cylindrical shape, these ends are the longitudinal ends. Preferably, each of the two electrical connections is used both for electrical tensioning and for the device for measuring the intensity of the electrical current: in this configuration, a single electrical connection is placed at each end of the porous medium. Thus, the system has two electrical connections. This configuration is advantageous because it makes it possible to limit the number of electrical connections. Alternatively, at each end of the porous medium, the system may include two electrical connections, one for the means of electrical tensioning and the other for the device for measuring the intensity of the electric current. Thus, the system then includes four electrical connections. This connection makes it possible to distinguish the two measurements.

 Electrical connections allow in particular to generate a voltage across the porous medium, that is to say between its ends and to measure the intensity of the electric current passing from one end to the other of the porous medium.

 Furthermore, the measurement system comprises control means for simultaneously carrying out radiographies by means of X-ray radiographies and electrical measurements by the device for measuring the intensity of the electric current.

Therefore, over time, the flow of the fluid in the porous medium can be observed by recording both x-rays and electrical measurements, in particular electrical resistivity measurements, simultaneously. The addition of electrical measurements is particularly interesting. Indeed, the electrical resistivity is directly related to the saturation in fluid. However, the electrical measurement undergoes a temperature-dependent drift over time at an amplitude although small than that of radiography. In addition, the drift of the electrical measurement is easily correctable by a known law, unlike that of radiography. Thus, two measurement points having a resistivity identical electric, under similar injection conditions, correspond to two identical saturation states. By similar injection conditions, it is meant that the fluid injection sequence is identical and that the distribution of fluid in the porous medium is identical (for example 35% of F1 and 65% of F2). By injection sequence is meant a succession of injections of at least one fluid, the succession of injections possibly comprising simultaneous injections of at least one fluid, preferably of several fluids. For example, an injection sequence can be constituted by the injection of a fluid F1 and then by the injection of a fluid F2.

 The use of X-ray images (2D images) allows faster measurement than that of tomography (also called CT Scan). Indeed, tomography reconstructs the 3D image by computer from multiple 2D radiography images taken all around the porous medium. It therefore requires a time to produce all 2D images and a time for computer reconstruction. The tomography technique therefore does not allow real-time monitoring either, unlike X-ray radiography.

 Determining the saturation in fluid from the resistivity measurement is, however, difficult to establish directly from the Archie equation because it depends on many parameters that it would be necessary to characterize. Indeed, Archie's formula is written as follows:

[Math 1]

 R,: resistivity of the porous medium

R _w : resistivity of the fluid

 porosity

S _w : fluid saturation

 a: tortuosity parameter

 m: cementing exhibitor

 n: saturation exponent

To determine S _w , it is necessary to know R _t , R _w and f as well as the three parameters a, m and n. The invention uses the stability character linked to electrical measurements to correct the intrinsic drift of X-ray radiographs.

The simultaneous measurement of radiographs and electrical measurements allows precise and reliable correction of radiographs. It thus allows good accuracy of the flow properties. Advantageously, the injection means can comprise a plurality of fluids to be injected into the cell, simultaneously or sequentially. Thus, the system is particularly suitable for EOR methods consisting of saturating the porous medium with a first fluid and injecting a second fluid, to extract at least part of the first fluid contained in the porous medium. The second fluid may in particular comprise surfactants. Preferably, one of the fluids can be an aqueous fluid and another fluid can be an oil. Advantageously, the aqueous fluid can comprise an additive, for example a surfactant. Therefore, the system is adapted to EOR characterizations.

 Preferably, the fluids of the plurality of fluids can have different electrical conductivities. As a result, it will be easier to characterize flow and saturation in various fluids.

Advantageously, the measurement system may include means for controlling the injection means. This allows, on the one hand, a more precise and reliable analysis of the results and on the other hand, the ability to modify the injection in real time, depending on the analysis results.

According to one embodiment of the invention, the measurement system may include means for analyzing the radiographs obtained by the detector. As a result, the analyzes can be carried out in real time, which makes it possible, on the one hand, to reduce the test time and on the other hand, to modify the injection conditions in real time according to the analyzes.

According to a preferred variant of the invention, the measurement system may include post-processing means which simultaneously performs the analysis of the radiographs obtained by the detector and the analysis of the electrical measurements obtained by the intensity measurement device electric current. Thus, post-processing is faster and possible in real time.

 In addition, the post-processing means can be configured to correct the radiographs from electrical measurements. Indeed, the measurement of electrical resistivity depending on the saturation in fluid and being a stable measurement (drift weak in time and easily correctable), it is possible to determine a correction factor from this measurement to correct the images of radiographies which undergo a drift over time, linked in particular to temperature variations.

To allow correction, for example, electrical measurement points are used, established at relatively distant times, for which the resistivity values are identical and with similar injection conditions. Indeed, the resistivity being directly related to the saturation of the fluid (via constant parameters), two values of identical resistivity, conducted under similar injection conditions, correspond to the same saturation state. Therefore, we can use this fact to correct the drift observed over time, on the gray levels obtained by radiographs, obtained at the same times. For this, the simultaneous realization of electrical measurements and radiographs is essential to obtain a correct correction and therefore a reliable and precise analysis.

Advantageously, the cell can have a substantially cylindrical shape. Thus, on the one hand, the production of the cell and that of the sample of porous medium are simpler and less expensive and, on the other hand, the circulation of fluid is facilitated and the pressure drops limited.

 According to an advantageous embodiment, the diameter of the cell can be substantially between 2 and 20 mm, and preferably between 5 and 10 mm. Indeed, the miniaturization of the cell is made possible by the characterization of the fluid saturation by means of radiographs and electrical measurement, without requiring the calculation of effluents. In addition, the use of a cell and therefore of a sample of small porous medium makes it possible to speed up the time for testing and analysis. Thus, we can obtain results more quickly and / or test more configurations.

 According to a variant, the height of the cell can be substantially between 2 mm and 5 cm, preferably between 5 mm and 2 cm. Indeed, the miniaturization of the cell is made possible by the characterization of the fluid saturation by means of radiographs and electrical measurement, without requiring the calculation of effluents. In addition, the use of a cell and therefore of a sample of small porous medium makes it possible to speed up the time for testing and analysis. Thus, we can obtain results more quickly and / or test more configurations.

According to one aspect, the system can be adapted for measuring the flow of an aqueous fluid and / or of an oil in the porous medium. Thus, it is particularly suitable for EOR (Enhanced Oil Recovery) applications.

 According to one implementation, the system can be adapted for measuring the flow of an aqueous fluid and / or an oil in the porous medium, the aqueous fluid comprising at least one additive, preferably a surfactant. Indeed, the surfactant is particularly advantageous for increasing the yields of oils produced in petroleum tanks.

In addition, the invention also relates to a method for measuring at least one flow property of at least one fluid within a porous medium, in which performs the following steps using the measurement system according to one of the preceding characteristics:

 a) An x-ray radiography of the porous medium is carried out simultaneously with an electrical measurement of the porous medium;

 b) Analyzing said electrical measurement and said radiography to determine said at least one flow property.

 Indeed, the simultaneous realization of radiographs and electrical measurements allows the simultaneous correlation of the measurements, and if necessary, the correction of the radiographs, by the information obtained by the electrical measurements.

 The analysis of electrical measurements and radiographs simultaneously allows the determination of the flow properties, precisely and reliably.

According to an implementation of the method according to the invention, during the analysis step, the electrical measurement can be used to correct the radiography, by the following steps: i. On the electrical measurement, measurement points corresponding to instants for which the electrical resistivity values obtained after similar injection conditions are identical are determined;

 ii. Correct said radiographs of a time drift using said electrical measurement points.

 Indeed, as the electrical measurements are stable over time (low drift and easily corrected) and they depend on the fluid saturation, the same resistivity value, obtained under similar injection conditions, corresponds to the same state saturation. Thus, these measurements can be used to correct the gray level drift obtained over time on the radiographs.

 According to a variant, the similar injection conditions may comprise the same sequence of injection of one or more fluids (for example an injection of a first fluid F1, followed by an injection of a second fluid F2) and a same distribution of fluids in the porous medium (for example, the porous medium comprises 35% of fluid F1 and 65% of fluid F2). In fact, resistivity depends on the different environments it crosses and their dynamics.

In accordance with an implementation of the method according to the invention, the flow properties can be chosen from the average saturation of the fluid, and / or the saturation profile of the fluid, and / or the electrical resistivity of the porous medium. Indeed, these properties are widely used for EOR applications in particular. According to one embodiment, a plurality of radiographies and electrical measurements can be carried out at regular intervals, preferably at intervals of between 0.1 and 10 seconds. Indeed, the construction of the curve is facilitated and the frequency allows a reliable reconstruction of the characteristics of the flow.

According to a variant of the method, a fluid can be injected into the porous medium, during the measurement step and / or during the analysis step.

 Preferably, the injection of the fluid into the porous medium can be controlled in real time during the measurements. Thus, we can use the analysis results to control the injection in real time. Thus, it is possible to quickly modify the test conditions as a function of the test results and thus reduce the experimentation time and / or increasing the number and / or the type of tests carried out.

[Fig 1] illustrates, schematically and without limitation, a measurement system according to an embodiment of the invention. The measurement system 1 comprises a cell 2 which contains the porous medium (for example a rock sample or a polymer). The cell 2 is placed in an X-ray protection cabin 3. In the cabin 3, there are also X-ray radiography means which include a source 4 of X-rays and a detector 5 of X-rays. The source 4 and the detector are positioned so that the X-rays emitted by the source 4 pass through the cell 2 before reaching the detector 5. Thus, the source 4, the cell 2 and the detector 5 are aligned or substantially aligned and the rays X start from source 4, reach cell 2 and then detector 5. Cell 2 is placed on a support which can be moved along three axes (represented schematically by arrows). The measurement system 1 also includes means 7 for injecting fluid into the cell. The injection means 7 are provided, in the example of [Fig 1], with four fluids, but they could be provided with more or less fluids. The injection means 7 are connected to the cell by four pipes (but there could be more or less pipes). The injection means 7 are arranged outside the X-ray protection cabin 3.

 In addition, the measurement system 1 also includes an electrical measurement means 8. This electrical measurement means 8 is connected by electrical connections to the two ends of the cell 2, and thus to the two ends of the porous medium, and thus makes it possible to '' apply electric current voltages / intensities across cell 2 (and porous medium) and / or measure electric current voltages / currents across cell 2 (and porous medium).

In addition, the measurement system 1 comprises a computer system 6. The computer system 6 is connected to the detector 5, to the injection means 7 and to the measurement means electrical system 8. The computer system 6 serves as means for controlling the injection means 7 and for means of collecting and analyzing, simultaneously, radiographies obtained by the detector 5 and electrical measurements, in particular electrical resistivities, obtained by the electrical measurement means 8. The electrical measurement means 8 comprises an electrical tensioning means and a device for measuring the intensity of electrical current. In addition, this computer system 6 includes post-processing means allowing correction in real time of the radiographs obtained from electrical measurements, the correction serving to correct the drift existing on the radiographs over time. The computer system 6 is arranged outside the protection cabin 3.

[Fig 2] illustrates, schematically and without limitation, an embodiment of the electrical measurement means 8 according to the invention. The electrical measurement means 8 and the radiography means composed of a source 4 and a detector 5 form a measurement system according to an embodiment of the invention. The cell 2 is positioned between the source 4 and the detector 5. Furthermore, the detector 5 and the electrical measurement means 8 are connected to the computer system 6 capable of managing the simultaneous information from the detector 5 and from the electrical measurement means 8, and transmit information in real time to the operator and / or to the control means (not visible in [Fig 2]).

 The electrical measurement means 8 comprises, in this embodiment, four connections to cell 2 composed as follows: two connections connect the electrical measurement means 8 to the upper terminal 11 of cell 2 (upper end) and two connections connect the electrical measuring means 8 to the lower terminal 12 of the cell 2 (lower end). Alternatively, the connections linked to the upper end of the cell 2 could be made by two electrically separated terminals and / or the connections linked to the lower end of the cell 2 could be made by two electrically separated terminals.

This arrangement makes it possible to impose an electrical voltage on the terminals, that is to say at the ends of cell 2 and therefore at the ends of the porous medium. It thus constitutes a means of electrical tensioning. The imposed potential difference is represented in [Fig 2] by V ⁺ and V. It then induces a displacement of the electrons represented by e which then causes an intensity of electric current in the medium and in the electric circuit generated between the device 8 and the cell 2, via the porous medium. Depending on the parameters of the porous medium, of the fluids contained in the porous medium and of the cell 2 itself, the electrical measurement means 8 measures the intensity of the current I and G which results therefrom at the ends of the cell (here via terminals 1 1 and 12). Thus, the electrical measuring means 8 comprises a device for measuring the intensity of the electric current. This measurement of the intensity of the electric current makes it possible to deduce the resistivity and if necessary the saturation in fluid of the porous medium and / or the profile of saturation.

Application example

 [Fig 3] and [Fig 4] show an example of application of the measurement system shown in Figure 1 with the detail of the electrical measurement device of [Fig 2]

 The porous medium tested is Bentheimer's sandstone of dimensions L = 1.8cm and D = 0.99cm. This porous medium initially contains two different fluids (a crude oil and a brine) in unknown proportions (saturation). During the measurements, a synthetic oil and brine are injected into the porous medium.

 During the injection, x-rays and electrical resistivity measurements are taken simultaneously every 10 seconds. [Fig 3] represents the variations in gray levels NG, in Joules, obtained from radiographs over time T, in minutes. This is the gray dotted RX curve. The RX curve is the raw data, that is to say without correction of the drift. In this figure, we also observe the recording of the electrical resistivity measurement Rs, in Ohm / m, by the continuous gray ME curve.

 When the fluid injection sequences are comparable (same fluid displacing the other fluid), two same resistivity values of the ME curve can be interpreted as states of the same saturation. Thus, on this curve ME, points of the same resistivity correspond to the same level of saturation and therefore one should have the same level of gray NG on the curve RX. Prec points are points of the same resistivity on the ME curve. There are three pairs of Prec points with the same resistivity: the first couple consists of points A1 and A2, the second of points B1 and B2 and the third of points C1 and C2. For each of these pairs of points, the gray level values NG observed on the RX curve should therefore be identical, which is not the case. We can note for example, that at the time of point A1, the gray level is slightly higher than 2530 while at the time of point A2, the gray level is almost 2540. Thus, the points Prec are used to correct the RX curve with information from the ME electrical measurement.

[Fig 4] shows different oil saturation curves So over time T, in minutes, corresponding to the above example. S1 is the oil saturation curve obtained from the radiographic images corrected by the Prec points of [Fig 3]: for two Prec points of the same resistivity on the ME curve of [Fig 3] (ie for each of the three pairs of points A1 / A2, B1 / B2 and C1 / C2), the gray level NG, from time T the greater of these two points Prec is corrected and is taken equal to the gray level NG from the smallest instant of these two Prec points (in other words, it is taken equal to the first Prec point observed, the drift being observed over time). We observe that at the instants corresponding to the points Prec, the oil saturations of the curve S1 are then identical (because directly related to the correction). The curves S2 represent the minimum and maximum values that the correction could have taken from an arbitrary realistic value obtained from the radiographs alone. The curves S2 correspond to the prior art. Thus, it is observed that thanks to the invention, the oil saturation obtained is much more precise and does not require the choice of an arbitrary correction factor, the correction according to the invention being based on factual observations and interpretations.

Claims

Claims

1) Measuring system (1) of at least one flow property of at least one fluid within a porous medium, said measuring system (1) comprising at least one cell (2) containing said porous medium , means for injecting (7) said fluid into said cell (2), and at least one X-ray radiography means comprising a source (4) and a detector (5), characterized in that the measurement system ( 1) comprises an electrical measurement means (8), said electrical measurement means (8) comprising an electrical tensioning means and a device for measuring the intensity of the electric current and at least two electrical connections, said means for electrical tensioning being connected to the ends of the porous medium by at least two of said electrical connections, said device for measuring the intensity of the electric current being connected to the ends of the porous medium by at least two of said electrical connections and that the measurement system (1) comprises control means for simultaneously carrying out radiographies by said means of X-ray radiographies and electrical measurements by said device for measuring the intensity of the electric current.

2) Measuring system (1) according to claim 1, for which said injection means (7) comprise a plurality of fluids to be injected into said cell (2), simultaneously or sequentially.

 3) Measuring system (1) according to claim 2, for which the fluids of said plurality of fluids have different electrical conductivities.

 4) Measuring system (1) according to one of the preceding claims, wherein said measuring system (1) comprises means for controlling said injection means (7).

5) Measuring system (1) according to one of the preceding claims, wherein said measuring system (1) comprises means for analyzing said radiographs obtained by said detector (5).

 6) measuring system (1) according to one of the preceding claims, wherein said measuring system (1) comprises post-processing means both for the analysis of said radiographs obtained by said detector (5) and for the analysis of said electrical measurements obtained by said device for measuring the intensity of the electrical current.

 7) Measuring system (1) according to claim 6, wherein the post-processing means is configured to correct said radiographs from said electrical measurements.

8) Measuring system (1) according to one of the preceding claims, wherein said cell (2) has a substantially cylindrical shape.

9) Measuring system (1) according to claim 8, wherein the diameter of said cell (2) is substantially between 2 mm and 20 mm, preferably between 5 mm and 10 mm. 10) Measuring system (1) according to claim 8 or 9, wherein the height of said cell (2) is substantially between 2 mm and 5 cm, preferably between 5 mm and 2 cm.

 1 1) Measuring system (1) according to one of the preceding claims, wherein the system is suitable for measuring the flow of an aqueous fluid and / or an oil in the porous medium.

 12) Measuring system (1) according to claim 1 1, wherein the system is suitable for measuring the flow of an aqueous fluid and / or an oil in the porous medium, said aqueous fluid comprising at least an additive, preferably a surfactant.

13) Method for measuring at least one flow property of at least one fluid within a porous medium, in which the following steps are carried out using the measurement system according to one of the preceding claims : An x-ray radiography of the porous medium is carried out simultaneously with an electrical measurement of the porous medium; then analyzing said electrical measurement and said radiography to determine said at least one flow property.

 14) Method according to claim 13, for which, for the analysis step, the electrical measurement is used to correct the radiography in the following manner: on said electrical measurement, measurement points are determined, said corresponding measurement points at instants for which electrical resistivity values, obtained after the same injection conditions, are identical; then correcting said radiographs of a time drift using said measurement points.

 15) The method of claim 14, wherein said same injection conditions include the same injection sequence of one or more fluids and the same distribution of said fluids in said porous medium.

 16) Method according to one of claims 13 to 15, wherein said flow properties are chosen from the average saturation of said fluid, and / or the saturation profile of said fluid and / or the electrical resistivity of said porous medium.

 17) Method according to one of claims 13 to 16, wherein a plurality of radiographs and electrical measurements are carried out at regular intervals, preferably at intervals between 0.1 and 5 seconds.

 18) Method according to one of claims 13 to 17, wherein a fluid is injected into the porous medium.

 19) Method according to claim 18, for which the injection of the fluid into the porous medium is controlled, in real time, during the measurements.