The present invention relates to the methods of measurement of thermophysical properties such as thermal conductivity of solid bodies, for example rocks.
Industrial application of thermal methods of oil recovery improvement implies prior simulation of heat and mass processes in reservoirs and wellbores as well as evaluation of thermal regime of downhole equipment. This fact raises the importance of problems concerned with the study of heat transfer in porous media (rock samples) that are composed of generally non-uniform solid skeleton and pores filled with one or several fluids gases or liquids.
Thermal conductivity (TC) is normally measured in the laboratory on core, crushed samples, or well cuttings using one of two techniques: divided bar or needle probe (see, for example, H.-D. Vosteen, R. Schellschmidt “Influence of temperature on thermal conductivity, thermal capacity and thermal diffusivity for different types of rock”, Physics and Chemistry of the Earth, 28 (2003), 499-509).
All these methods provides for thermal treatment of the samples followed by measurements. But heating is not desirable for liquid-filled samples since at heating the liquid partly vaporizes and forms gas locks inside the pore space which results in thermal conductivity error.
Physical models that were developed for effective TC calculation include three parameters: solid phase TC, saturating phase TC and microstructure of porous space. Ones the detailed internal microstructure of rock samples is obtained it become possible to determine the effective TC solving the thermal conductivity equation numerically (S. V. Patankar, ‘Numerical Heat Transfer and Fluid Flow’, Taylor&Francis, 1980, pp. 59-61). The direct numerical solution of thermal conductivity equation can be extraordinarily challenging when all the details of the complex 3D rock microstructure are accounted for. Sometimes it is impossible to apply this method because of significant expenses of computing time spent to perform calculations and incredibly expensive cost of computer resources needed for such simulations carrying out.
The proposed method allows fast estimation of effective thermal conductivity and does not require solving thermal conductivity equation numerically. This method relies only on core microstructure captured by the means of X-ray micro-computed tomography system (micro-CT) and comprises the steps of providing a core sample and an X-ray micro-computed tomography scanner (micro-CT) for scanning said core sample and generating an image for each scan, scanning said core sample, transferring the three dimensional scan images from the CT scanner to an image analysis computer for processing, setting a layer thickness to be analyzed, defining a layer with maximum thermal resistance within the produced three dimensional scan image and defining the core sample effective thermal conductivity.
The layer with maximum thermal resistance is a layer with the minimum total surface porosity.
The layer thickness to be analyzed is selected taking into account the core sample dimensions and the dimension of voxels.
Digital rock models can be constructed from 2D thin sections, scanning-microCT, CTscans are 2-dimensional (2D) cross sections generated by an X-ray source that rotates around the sample. Density is computed from X-ray attenuation coefficients. Scans of serial cross sections are used to construct 3D images of the sample. Because the density contrast is high between rocks and fluid-filled pores, CT images can be used to visualize the rock-pore system. Resolutions are on the sub-millimeter to micron scale, depending on the device being used.
X-ray computed tomography, or CT scan, is an important nondestructive core imaging technique. CT scans produce X-ray pictures of a series of contiguous equidistant 2D slices.
The present invention utilizes the following procedure to determine thermal conductivity of a core sample.
An X-ray CT scanner used is a third generation scanner where the source and detector are fixed and the scanned object rotates. A rock sample is placed on a turntable and horizontal X-ray beams generated from the X-ray source penetrate through the sample before they reach the detector. The source or sample is rotated by 360 degrees during the scan when the attenuated X-ray intensities are measured and the recorded attenuation profile of the slice can be transformed to a crosssectional image. The sample is then shifted vertically by a fixed amount and the scan is repeated multiple times until the whole sample is imaged.
The core sample which structure has been obtained using micro-CT is shown in
This scanned image is then transferred to an image analysis computer for processing.
The layer with maximum thermal resistance defines thermal flux. Therefore it is necessary to find the layer with maximal thermal resistance. The criterion of search is the minimum surface porosity of allocated layer
In order to describe the suggested method of core TC estimation the case, when allocated layer consists of two cells in direction of heat conduction is considered (
where Δx is voxel resolution in axis X direction, m; δT=T2−T1, where T1 and T2 are values of temperature on opposite sample faces which are perpendicular to X axis, K. The dimensions of sample (Fig.2) can be determined as follows:
δxΔx·Nx δy=Δy·Ny δz=Δz·Nz,
where Δy, Δz are voxel resolution in direction of Y and Z axis, m; Nx, Ny and N2—number of cells along X, Y and Z axis, correspondingly. The value of thermal flux in X direction through two contiguous cells with indexes (j;k) endwise Y and Z axis is determined by the following formula:
where λjk1 and λjk2 are the TCs of cells in allocated layer. Here the indexes 1 and 2 refer to the first and the second cells of allocated layer in X direction, respectively. The expression (2) can be transformed to the following view:
Thermal heat flux through all allocated cells layer in X direction is calculated in the following way:
where
is effective TC in X direction of two contiguous cells with equal indexes (j;k) endwise Y and Z axis.
From the other side thermal flux through sample in X direction is determined by expression:
If we equate formulas (4) and (5) we will define effective TC as follows:
Transformation of expression (6) gives:
After making (6) dimensionless it takes the following form:
where φ1, φ12 and φ2 are surface parts of filling of considered layer only with rock core, rock core together with fluid and only with fluid correspondingly. The values of quantities φ1, φ12 and φ2 are defined with the following expressions:
The quantity φ1 is also used in order to determine the minimum total surface porosity of allocated layer—ε For this purpose the following term is used:
ε=1−φ1 (9)
Now the case when allocated layer consists of m cells in X direction, at that m is odd number is considered. In this case temperature difference between the medium of first and last cells of allocated layer are defined as:
Then thermal flux through layer from m cells is calculated as follows:
Here λjkef
Then thermal flux through layer with thickness equal to m cells in X direction is defined as given below:
Using expressions (5) and (10) and making several transformations the result term for effective TC determination for layer containing m cells in X direction can be written as follows:
The estimation of TC using proposed method has been done for sample of 240×240×240 voxels. The comparison of calculated TC with precise solution has shown that the error of estimation doesn't exceed 3.6% for considered sample.
With the use of proposed method the determination of tensor components of relative effective TC was carried out for two core samples with the size of 1800×1800×1800 voxels. For the first sample the variation of allocated layer thickness in direction perpendicular to heat conduction was made. The interval of variation was from 3 to 21 cells while the layer thickness changed from 15 to 105 microns. The influence of layer thickness for sample saturated with air and water was studied. For this sample the optimal thickness of allocated layer was 11-15 cells. In this case an error of effective TC determination using approximate method as compared with upscaling procedure was not more than 5%. So in order to estimate TC of core samples with size 1800×1800×1800 voxels and cell dimension in 5 microns the allocated layer thickness is set to 13 cells.
The dependence of effective TC tensor components from relative TC of saturating medium for the second sample is presented in
The duration of numerical estimation of effective TC tensor components for one sample with size in 1800×1800×1800 cells was in the order of 1000 seconds of CPU time.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/RU2009/000758 | 12/31/2009 | WO | 00 | 10/12/2012 |