This invention relates to the field of hydrocarbon exploration and production, and more particularly to resistivity logging. Specifically, the invention is a method for the inversion of multi-components/tri-axial induction measurements in a fractured reservoir and cross-bed sand to yield characterization of anisotropic resistivity with biaxial symmetry. An inversion scheme and method is disclosed that can use all nine tensor components of induction measurements, borehole azimuth, and deviation data.
Resistivity is one of the most important parameters measured in wells for hydrocarbon exploration and production. For many years, conventional induction tools have been built with coils that have magnetic moment along the tool axis (co-axial dipole) that is mainly sensitive to the horizontal resistivity when the formation is horizontal and the well is vertical. Different designs of co-axial multi-coils array induction has appeared in the literature for over 30 years. Although theoretical work on resistivity anisotropy measurements started in 1950's (See Kunz and Moran, “Some effects of formation anisotropy on resistivity measurements in boreholes,” Geophysics 23, 770-794 (1958)), and the detailed theoretical derivation on the magnetic moment perpendicular to the tool axis (co-planer dipole) was also published in 1979 (Moran and Gianzero, “Effects of formation anisotropy on resistivity logging measurements,” Geophysics 44, 1266-1286 (1979)), the multi-component/tri-axial induction tool was not introduced into commercial service until the first decade of the 21st century. First, Baker Atlas commercialized its multi-component tool-3DEX (Schon et. al., “Aspects of Multicomponent resistivity data and macroscopic resistivity anisotropy,” SPE 62909 (2000)), and Schlumberger introduced their version of a tri-axial induction tool-AIT-Z (Rosthal et al., “Field test results of an experimental fully tri-axial induction tool”, SPWLA 44th Annual Symposium, Paper QQ (2003)); and Barber et. al., “Determining formation resistivity anisotropy in the presence of invasion”, SPE 90526 (2004)). However, these multi-component/tri-axial component tools have been mainly marketed as a thin-bed, low-resistivity-pay tool to invert horizontal and vertical resistivity Rh, and Rv, to be used with assumptions of vertical transverse isotropy (“VTI”) symmetry for (for example) thinly laminated formation, or Horizontal Transverse Isotropy (HTI) symmetry for vertical fractures (Rabinovich et al., “Determination of fracture orientation and length using multi-component and multi-array induction data,” U.S. Patent Application No. 2005/0256645 (2005)). Within the framework of a transverse isotropic model, Rv is assumed to be greater than Rh. (The tool used is designed mainly as a thin-bed tool for laminated formations. Then, in thinly laminated sand-shale sequences with high-low resistivity, the series combination of resistances (Rv) must be greater than the parallel combination (Rh).) Hence, when the inverted Rh is greater than Rv, one solution that has been used to reconcile this conflict is to force the horizontal resistivity to be equal to vertical resistivity, Rh=Rv, i.e., isotropy.
As shown in the schematics of
In many cases, the above expression cannot be realized by rotation and inversion because the formation simply has higher anisotropic symmetry than VTI system.
What is needed is an inversion method that can use all nine components that can be measured by tri-axial induction tools, plus borehole azimuth and deviation data, to address these issues and solve for the tri-axial induction response in an arbitrary anisotropic formation due to the non-orthogonal bedding plane and fracture plane (or cross bedding plane). The present invention provides such a method.
In one embodiment of the present inventive method, referring to the flow chart of
(a) expressing a formation conductivity tensor with components as measured by the well logging tool (step 101), wherein each component of said tensor is expressed (step 102) as a combination of the conductivity components:
(b) inverting the expression for the formation conductivity tensor to obtain σnb, σpb, σnf, and σpf from the measured conductivity data (step 103); and
(c) detecting one or more fault planes from indications of anisotropy in the inversion results (step 104).
In some embodiments of the invention, azimuth and dip angles for the fault planes and azimuth and dip angles for the tri-axial induction well logging tool are also obtained from the data inversion.
The present invention and its advantages will be better understood by referring to the following detailed description and the attached drawings in which:
The invention will be described in connection with its preferred embodiments. However, to the extent that the following detailed description is specific to a particular embodiment or a particular use of the invention, this is intended to be illustrative only, and is not to be construed as limiting the scope of the invention. On the contrary, it is intended to cover all alternatives, modifications and equivalents that may be included within the spirit and scope of the invention, as defined by the appended claims.
The present invention is a method for inverting reservoir bi-axial anisotropy and identifying complicated fracture/cross-bedding system by using tri-axial induction logs and wellbore survey/image log data. Bi-axial anisotropy is a direct indication of fracture/cross-bedding reservoir rock, and has a significant impact on reservoir characterization, e.g. hydrocarbon pore fluid estimation. The present inventive method will yield profiles of Rxx, Ryy and Rzz, from which it will be possible to ascertain the presence of faults, among other benefits of knowing the resistivity model in its full, anisotropic complexity.
Description of Biaxial Resistivity System
Next, the conductivity equations for the biaxial anisotropic resistivity formation will be developed by considering four, progressively more general, cases.
Uniaxial/VTI Bed and Orthogonal Fault/Fracture System
One example of a biaxial anisotropic formation may be described as laminated beds intercepted by perpendicular fault/fractures (53 in
(a). Conductivity normal to bedding plane (σnb);
(b). Conductivity parallel to bedding plane (σpb);
(c). Conductivity normal to fault plane (σnf); and
(d). Conductivity parallel to fault plane (σpf).
Note that VTI is a function of σnb and σpb, and HTI is a function of σnf and σpf.
Then, the tensor conductivity {right arrow over (σ)} in the X, Y, and Z directions, is simply the summation of the conductivity in each direction:
Uniaxial/VTI Bed Intercepted by Fault/Fracture Plane with α° Dip
If the fault/fracture plane 62 is rotated α° about the Y-axis as shown in the schematic diagram of
Uniaxial/VTI Bed Intercepted by Fault/Fracture with α° Dip and β° Azimuth/Strike—a General Biaxial Anisotropic Case
If in addition to the rotation shown in
The conductivity {right arrow over (σ)} in the X, Y and Z directions for such a general biaxial anisotropic case is given by the summation of conductivity in each direction with a fault/fracture dip equal to a rotation of α° and an azimuth/strike of the fault/fracture plane equal to a rotation of β°:
General Biaxial Anisotropic System with Arbitrary Orientation
A general 3-D biaxial anisotropic resistivity model includes tool axis or borehole with arbitrary deviation angle and strike angle penetrating a series of anisotropic or isotropic beds (with arbitrary dip and strike angles).
Such a generic anisotropic case can be set up using the coordinate system for 3-D resistivity measurement by multi-component/tri-axial tools as shown in
For convenience, the double-prime superscript is dispensed with in writing the individual tensor components. Equation (5) can be expressed in terms of σnb, σpb, σnf and σpf by substituting the relationships (4).
The conductivity tensors in either the cross bedding plane or faults/fracture plane (or planes if there are multiple fractures) in the X″-Y″-Z″ coordinates can be coupled to the borehole axis coordinates X-Y-Z by the following transformation:
The strike angle of the fracture/cross-bedding plane β with respect to the formation boundary plane can be arbitrary when the fracture/cross-bedding dip angle α is zero. Similarly, the strike of the tool βtool (or borehole) with respect to the formation boundary plane can be arbitrary when tool deviation (e.g., borehole deviation) αtool is zero, i.e., the borehole is vertical.
Theory and Method of Inversion
3D Modeling in Biaxial Anisotropic System
In the above treatment, a general biaxial anisotropy system was formed by two simple uniaxial anisotropic systems with rotations of arbitrary dip and azimuth angle in a forward modeling scheme for computer simulation of synthetic magnetic moment or voltage data (from which conductivity can be calculated). For such a general biaxial anisotropic system with arbitrary borehole orientation as shown in
The inversion process can be designed to match and/or minimize the differences between the computer generated synthetic data in the coordinates of the bi-axial anisotropic system and the field data measured by multi-component/tri-axial tools in the form of magnetic moments Hij (see the previously cited paper by Schon, et. al.), or voltage Vij (previously cited papers by Rosthal et al. and Barber et al.) by iteratively updating the borehole and formation parameters. A tri-axial/multi-component resistivity tool may be constructed with paired transmitters and receivers with multi-frequency measurement channels, or multi-spacings of the transmitter and receiver pairs and each pair can also contain three orthogonally oriented transmitters (TX, TY and TZ) and receivers (RX, RY and RZ) with the same spacing L(i). This arrangement is illustrated in
where what the tri-axial/multi-component resistivity tool measures is either magnetic field/moment H or the voltage V it induces in the receiver's coil. In an appropriately chosen system of units, H over V is a scalar.
Resistivity logging is based on exciting a source coil with an AC voltage, resulting in a magnetic field generated by the source coil. This magnetic field induces eddy currents in the formation that further induce an AC voltage in a receiver coil, which is measured and recorded. The formation conductivity can be calculated from the known transmitter and receiver parameters and geometry, resulting in a relationship between measured V or H and formation conductivity. This is a tensor relationship in an anisotropic medium. This relationship between the tensor conductivity σij and the tri-axial dipole magnetic moments Hij can be expressed as:
{right arrow over (σ)}ij=Cij*{right arrow over (H)}ij (8)
where Cij is a coupling matrix, determined by the well logging tool's design. Each geophysical service company will be able to provide these parameters for its tool.
Therefore, equation (8) is substituted into equation (6) for σ, and equation (6) is then inverted to yield σ″. Mathematically, a process for the inversion of Equation (6) can be realized by least-square optimization (see, for example, Zhdanov et al., “Foundation of tensor induction well logging,” Petrophysics 42 (2001)), but the invention is not limited to this or any other particular optimization or updating scheme, and a misfit measure, or objective function, can be defined as:
φ(mp)=∥Hij(d)−Hij(c)∥ (9)
where Hij(d) and Hij(c) are, respectively, the measured data from the tool and the predicted data from 3D computer simulation using equation (6) based on the values for the seven unknowns assumed for the present iteration cycle.
1D Modeling in Biaxial Anisotropic System Composed of Two TI Systems
The conductivity tensors in either the cross-bedding plane or fracture plane (or planes if a system of multiple fracture sets) expressed in the X″-Y″-Z″ coordinate system can also be iteratively solved for through Equation (4) defined by the two orthogonal TI system, i.e., using the tensor conductivity {right arrow over (σ)} in Equation (4) composed of the four basic conductivities, σnb, σpb, σnf, and σpf, and the relative dip α and azimuth β between the VTI bedding system and HTI faults/fracture/cross-bedding system. In such a case, the 1D solution described in the Appendix in Anderson et al., “The effect of crossbedding anisotropy on induction tool response”, Petrophysics 42, 137-149 (2001), which is incorporated herein by reference, can be reformulated and applied twice orthogonally, and the conductivity tensors {right arrow over (σ)} can be summed as defined by Equation (4). This 1D+1D approach is a less rigorous way of inverting Equation (6) than an approach such as iterative updating using an objective function as outlined above, but it will significantly reduce the forward computation time, and may be the preferred embodiment of the invention from a practical standpoint. However, these two inversion techniques are examples only, and the present inventive method includes any method of inverting Equation (6) or any equivalent relationship.
Constraints from Related Measurements and Rock Physics
The following features can be advantageously incorporated in the invention, depending upon the circumstances, although they are not essential to the invention.
In the step of the initial iteration, the measured borehole deviation survey data can be used to restrain the initial values of the variables αtool, βtool.
Define VTI anisotropic ratio λ=σpb/σnb, and HTI anisotropic ratio μ=σpf/σnf.
In hydrocarbon saturated anisotropic systems, it may be assumed that σpb>>σnb, e.g., λ=σpb/σnb>>1, and, σpf>>σnf, e.g., μ=σpf/σnf>>1. It may be possible to determine these anisotropic ratios from core plug measurements.
In water saturated anisotropic systems, it may be assumed that σpb>σnb, e.g., λ=σpb/σnb≈1-3, and, σpf>σnf, e.g., μ=σpf/σnf>>1-5. It may be possible to determine these anisotropic ratios from core plug measurements.
With these physical and geological/geographical data constraints, the seven unknown parameters αtool, βtool, α, β, σxx, σyy, σzz in Equation (6) can be reduced down to five (α, β, σxx, σyy, σzz), or even fewer, for a more manageable inversion process and more robust results.
The foregoing application is directed to particular embodiments of the present invention for the purpose of illustrating it. It will be apparent, however, to one skilled in the art, that many modifications and variations to the embodiments described herein are possible. All such modifications and variations are intended to be within the scope of the present invention, as defined in the appended claims.
This application is the National Stage entry under 35 U.S.C. 371 of PCT/US2008/079203 that published as WO 2009/070384 and was filed on 8 Oct. 2008, which claims the benefit of U.S. Provisional Application No. 61/004,875, filed on 30 Nov. 2007, each of which is incorporated by reference, in its entirety, for all purposes.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2008/079203 | 10/8/2008 | WO | 00 | 3/12/2010 |
Publishing Document | Publishing Date | Country | Kind |
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WO2009/070384 | 6/4/2009 | WO | A |
Number | Name | Date | Kind |
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3014529 | Graham | Dec 1961 | A |
7066282 | Chen et al. | Jun 2006 | B2 |
7629791 | Bespalov et al. | Dec 2009 | B2 |
20030055565 | Omeragic | Mar 2003 | A1 |
20050140373 | Li et al. | Jun 2005 | A1 |
20050256645 | Rabinovich et al. | Nov 2005 | A1 |
20070244646 | Zhang et al. | Oct 2007 | A1 |
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Number | Date | Country | |
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20100230095 A1 | Sep 2010 | US |
Number | Date | Country | |
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61004875 | Nov 2007 | US |