Exploration and production (E&P) of hydrocarbons in a field, such as an oil field, may be analyzed and modeled. The analysis and modeling may include sedimentary basin simulation, subsurface hydrocarbon reservoir charge modeling, geological modeling, subsurface rock formation petrophysical properties evaluation, and downhole fluid analysis. Based on the result of the analysis and modeling, hydrocarbons may be extracted from the field. Thus, accurate models are useful for the extraction of hydrocarbons.
Acoustic measurements may be used to evaluate a borehole in a geological formation. Generally speaking, downhole sonic tools may use monopole or dipole sonic transmitters to obtain sonic measurements. A monopole transmitter emits energy equally in omni-direction away from its center, while a dipole transmitter emits energy in a particular direction. To identify fractures in a borehole, monopole transmitters may be used in what is referred to as a low frequency Stoneley waveform analysis. Specifically, a Stoneley wave propagates along the interface between the borehole fluid and the formation. Thus, the monopole low frequency sonic signal may attenuate depending on characteristics of the geological formation along the borehole, such as a fracture or permeable zone. Accordingly, monopole Stoneley waveform analysis may be a useful tool to identify fracture or permeable zones in a borehole.
Monopole waveforms may include multiple packets of coherent arrivals that include monopole refracted headwaves followed by a sequence of borehole modal arrivals, such as, the Stoneley and pseudo-Rayleigh modes. Monopole refracted headwaves may include monopole compressional and shear headwaves. Monopole compressional headwaves may be recorded by an array of receivers in both the fast and slow formations, whereas monopole shear headwaves may be detected only in fast formations.
This summary is provided to introduce a selection of concepts that are further described below in the detailed description. This summary is not intended to identify key or essential features of the claimed subject matter, nor is it intended to be used as an aid in limiting the scope of the claimed subject matter.
In one aspect, embodiments disclosed herein may relate to a method for estimating all five transversely-isotropic (TI)-elastic constants using borehole sonic data obtained from at least one subterranean borehole in a transversely isotropic formation, the method may include: solving for a quasi-compressional qP-wave velocity VqP using inversion algorithms based on exact solutions of the Kelvin-Christoffel equations for plane wave velocities in arbitrarily anisotropic formations, where the five TI-elastic constants may include C11, C13, C33, C55, and C66.
In another aspect, embodiments disclosed herein may relate to a method for estimating all five transversely-isotropic (TI)-elastic constants using borehole sonic data obtained from a horizontal borehole in a transversely isotropic formation, the method may include: recording monopole and cross-dipole waveforms at an array of receivers in the horizontal borehole parallel to an X1-axis that is perpendicular to a TI-symmetry X3-axis; processing the monopole refracted headwaves to output monopole compressional modulus C11; processing fast-dipole waveforms to estimate shear modulus C66; processing slow-dipole waveforms to estimate shear modulus C55; solving three travel-time equations for C33, C13, and reflector distance D, using as inputs C11, C55, C66 from the borehole sonic data from the horizontal borehole, where reflection data analysis provides estimates of arrival times t1, t2, t3; sub-array offsets z1, z2, and z3; and ray-path directions θ1, θ2, and θ3, where the horizontal borehole is parallel to an X1-axis that is perpendicular to a TI-symmetry X3-axis, and where the method may further include outputting the five TI-elastic constants and the reflector distance D based on a weak anisotropy assumption for the quasi-compressional wave velocity VqP (θ).
In another aspect, embodiments disclosed herein may relate to a system for locating hydrocarbons in a transversely-isotropic (TI) formation including: a borehole sonic tool that measures borehole sonic data along at least one subterranean borehole in the formation; a processor that processes the borehole sonic data to determine all five TI-elastic constants as a function of position along at least one borehole; an output device that outputs the five TI-elastic constants as a function of position along the borehole, where determining the five TI-elastic constants may include: solving for a quasi-compressional qP-wave velocity VqP using inversion algorithms based on exact solutions of the Kelvin-Christoffel equations for plane wave velocities in arbitrarily anisotropic formations, and where the five TI-elastic constants may include C11, C13, C33, C55, and C66.
Other aspects and advantages of the claimed subject matter will be apparent from the following description and the appended claims.
Organic rich shale reservoirs may exhibit Transverse Isotropy (TI) with the vertical symmetry axis (TIV), but producing wells are often drilled horizontally. TIV formations may be characterized by three Thomsen parameters, ε, δ, and γ, which can predict sonic velocities from VP0 and VS0 in terms of the well's deviation from the vertical axis. VP0 and VS0 denote the compressional and shear velocities for propagation direction parallel to the TI-symmetry (X3-) axis and the deviation from the TI-symmetry axis is 0 degree. These parameters may be derived from two or more wells with different well deviations or by inverting flexural wave dispersion in a vertical well. The majority of production from organic rich shales is often from horizontal wells, and an accurate characterization of the anisotropic elastic properties of these formations may be relevant for hydraulic fracture design and simulation monitoring using micro-seismic.
A Transversely-Isotropic (TI) formation may be characterized by five independent TI-elastic constants (C11, C33, C44, C66, and C13) as in Eq. (17) below. These TI-elastic constants may be used to calculate elastic stiffnesses in different directions with respect to the borehole axis. Elastic stiffnesses may be described in terms of vertical and horizontal Young's moduli and Poisson's ratios. Here the vertical direction is parallel to the TI-symmetry axis and horizontal plane is perpendicular to the vertical direction. Hydraulic fracturing of formations for stimulating enhanced hydrocarbon production may be facilitated by identifying intervals that would support deep fractures for the fluid to flow into the producer well. Such intervals may be identified as regions with higher fracturability and may be characterized by large Young's moduli and small Poisson's ratios; they are sometimes also referred to as brittle rocks. Mechanical properties of formations in terms of Young's moduli and Poisson's ratios may be estimated from the five TI-elastic constants. In addition, formation stress distributions may also be estimated from the five TI-elastic constants. Generally, hydraulic fractures are bound by layers with higher stresses than the hydrocarbon-bearing layer.
Estimation of all five TI-elastic constants may require measurements of the quasi-compressional (qP), pure shear (SH) and quasi-shear (qSV) wave velocities along boreholes with different deviations from the TI-symmetry axis within a reasonably uniform lithology interval. A reasonably uniform lithology interval may refer to a shale formation in the presence of thin layers with small contrasts (<10%) in elastic stiffnesses from the host shale rock formation. In particular, such interbedded layers may not cause any reflections of elastic waves at sonic frequencies ranging from 0.2 to 20 kHz.
A quasi-compressional wave is a general term that covers any propagation direction of the wave from the TI-symmetry axis. These velocities may be reliably estimated from a conventional processing of monopole and cross-dipole waveforms. Monopole waveforms may be generated by a monopole source. Cross-dipole waveforms may be generated by two orthogonal dipole sources. These sources may be located on a sonic tool. Fast-dipole and slow-dipole waveforms may be generated by two orthogonal dipole transmitters oriented parallel to the fast- and slow-shear polarization directions, respectively. These waveforms may be recorded by two sets of orthogonal receivers aligned with the fast and slow dipole sources or transmitters.
In one or more embodiments, monopole refracted headwaves may be generated by a monopole source, or transmitter, and may be recorded by an array of hydrophone receivers such as those located on a sonic tool. The received monopole signals may then be processed to obtain compressional or quasi-compressional velocities.
In one or more embodiments, algorithms invert the qP, qSV, and SH wave velocities in a given depth interval with a reasonably uniform lithology obtained from any of the following four different combinations of borehole deviations: (a) vertical and deviated; (b) horizontal and deviated; (c) two different deviations; and (d) vertical, horizontal and deviated.
In one or more embodiments, algorithms use sonic data from a single horizontal borehole together with reflection data from a horizontal proximate stiff layer, e.g., a limestone layer, acquired at multiple sub-arrays of receivers in the horizontal borehole.
In one or more embodiments, algorithms use sonic data from a single horizontal borehole together with refraction and reflection data from a horizontal proximate stiff layer, e.g., a limestone layer, acquired at multiple sub-arrays of receivers in the horizontal borehole.
In accordance with one or more embodiments of the present disclosure, inversion algorithms are based on exact solutions of the Kelvin-Christoffel equations for plane wave velocities in arbitrarily anisotropic formations. Closed-form expressions for the TI-elastic constants do not use any weak anisotropy approximation.
Horizontal drilling in organic-shale reservoirs is often used to produce hydrocarbons commercially. However, optimal placement of fracturing stages and perforation clusters along lateral producer wells becomes a challenging task when the formation stresses and mechanical property logs do not capture shale heterogeneities. Some techniques of estimating all five TI-elastic constants are based on using sonic data from multiple wells with different deviations that invariably average anisotropic properties over large volumes of shale reservoirs. To overcome these limitations, it is desirable to obtain all five TI-elastic constants from a single horizontal well data.
Methods in accordance with the present disclosure may utilize new techniques that enable estimates of all five TI-elastic constants of the shale reservoir as a function of logged depth along a lateral producer well. In one or more embodiments, methods may combine horizontal well sonic data processing with the reflection and refraction data obtained in the presence of a horizontal proximate stiff layer, e.g., limestone (or other stiff stringers) embedded in a shale formation. Stringers may be defined as thin and stiff layers embedded in a relatively thick sand or shale formation. Outputs from a horizontal well sonic data processing may yield three of the five TI-elastic constants, whereas combining sonic data with the reflection and refraction data provide the remaining two TI-elastic constants. Once all five TI-elastic constants are determined with the axial resolution of a sonic tool along a horizontal well, formation horizontal stresses and rock mechanical properties may be known as a function of logged depth, where logged depth is understood to be a position along the borehole and may be different from true vertical depth (TVD). High axial resolution of stresses and mechanical properties may enable a more reliable completion strategy of properly placing the fracturing stages and perforation clusters in the presence of local shale heterogeneities.
Sonic tools in accordance with the present disclosure may include a sonic source placed in a fluid-filled borehole that generates headwaves as well as other borehole-guided modes. A sonic measurement system in accordance with the present disclosure may include placing a piezoelectric source and an array of hydrophone receivers inside a fluid-filled borehole. Piezoelectric sources may be configured in the form of either a monopole, dipole, or quadrupole source. The source bandwidth may range from a 0.2 to 20 kHz in some embodiments. Monopole sources in accordance with the present disclosure may generate lowest-order axisymmetric modes, also referred to as a Stoneley mode, together with quasi-compressional and shear headwaves in fast formations. A fast formation is characterized as a formation in which the formation shear wave velocity is larger than the borehole-liquid (mud) compressional wave velocity.
In contrast, dipole sources may excite lowest-order flexural borehole mode together with quasi-compressional and shear headwaves. Shear headwaves are produced by the coupling of the transmitted sonic energy to plane waves in the formation that propagate along the borehole axis. An incident quasi-compressional wave in the borehole fluid produces critically refracted quasi-compressional waves in the formation. Those refracted along the borehole surface are known as quasi-compressional headwaves. The critical incidence angle θi=sin−1(Vf/Vc), where Vf is the quasi-compressional wave speed in the borehole fluid; and Vc is the quasi-compressional wave speed in the formation. As the quasi-compressional headwave travels along the interface, the quasi-compressional headwave may radiate energy back into the fluid that may be detected by hydrophone receivers placed in the fluid-filled borehole.
In fast formations, the shear headwave may be similarly excited by a quasi-compressional wave at the critical incidence angle θi=sin−1(Vf/Vs), where Vs is the shear wave speed in the formation. It is also worth noting that headwaves are excited only when the wavelength of the incident wave is smaller than the borehole diameter so that the boundary may be effectively treated as a planar interface. In a homogeneous and isotropic model of fast formations, as above noted, quasi-compressional and shear headwaves may be generated by a monopole source placed in a fluid-filled borehole for determining the formation quasi-compressional and shear wave speeds. Refracted shear headwaves cannot be detected in slow formations (where the shear wave velocity is less than the borehole-fluid compressional wave velocity) with receivers placed in the borehole fluid. In slow formations, formation shear wave velocities may be obtained from the low-frequency asymptote of flexural dispersion. There are standard processing techniques for the estimation of formation quasi-compressional and shear wave velocities in either fast or slow formations from an array of recorded dipole waveforms. One of the techniques is based on a Slowness-Time-Coherence (STC) processing algorithm that estimates a non-dispersive slowness of an arrival from an array of waveforms over a chosen frequency filter and sampling window, where wave slowness is the inverse of wave velocity.
Another technique uses variations of Prony's algorithm, such as a modified matrix pencil algorithm, which isolates both dispersive and non-dispersive arrivals in a recorded wavetrain. Sonic logging may provide measurements of non-dispersive and dispersive arrivals that may be analyzed to estimate elastic properties of the propagating medium. In addition, monopole and dipole sources may generate plane quasi-compressional and shear waves into the surrounding formation at different incidence angles that are reflected back from a stiffer layer into the formation and may be detected by the hydrophone receivers located close to the borehole surface. When the incident wave strikes the stiffer layer at a critical angle, the refracted plane wave propagates along the interface of the layer and formation. Subsequently, this refracted wave travels back to the formation and may also be detected by the hydrophone receivers placed close to the borehole surface. Plane wave velocities and polarization vectors for wave propagation along an arbitrary direction in anisotropic formations may be described by the Kelvin-Christoffel equations of motion in the transformed coordinate system that eliminates the need for obtaining the polarization vectors defined with respect to the anisotropy axes.
A borehole sonic tool measures the quasi-compressional, two shear, and Stoneley wave slownesses for propagation along the borehole axis. An arbitrarily deviated borehole may have an azimuth φ from the north, and a deviation θ from the vertical. If X1-, X2-, and X3-axes are along the north, east, and vertical directions, respectively, rotation about the X3-axis defines the well azimuth φ, and rotation about the X1-axis denotes the well deviation θ. The deviated well axis is now parallel to the X3″-axis, and the cross-sectional plane is in the X1″-X2″ plane. The well azimuth φ and the well deviation θ are also referred to as the two Euler angles for the rotated axes referred to the reference X1-, X2-, and X3-axes.
The propagation of plane waves along any of the rotated X1″-, X2″-, or X3″-axes may now be described by Eq. (1):
C
ijkl
∥
u
k,li
=ρii
j, (1)
where C∥ijkl denotes the rotated TI-elastic constants, and is related to the TI-elastic constants in the reference coordinate axes by the following orthogonal transformation of a fourth-rank tensor shown in Eq. (2):
C
ijkl
∥
=a
ip
a
jq
a
kr
a
ls
C
pqrs, (2)
and the rotation matrix aij is given by Eq. (3):
where φ and θ are the first two Euler rotations about the X3-, and X1|-axes, respectively. The third rotation ψ about the X3∥-axis is assumed to be zero.
The propagation of plane waves along the deviated borehole X3∥-axis may be described by Eq. (4)
C
3jk3
∥
u
k,33
=ρü
j (4)
where the plane wave solution referred to the rotated axes is now expressed as in Eq. (5):
u
j
=A
j
e
ik
(x
−Vt). (5)
Eq. (4) may be written as shown below in Voigt's compressed notation for the elastic stiffnesses referred to the rotated axes and after suppressing double primes on the TI-elastic constants for clarity as expressed in Eqs. (6)-(8):
C
55
u
1,33
+C
45
u
2,33
+C
35
u
3,33
=ρii
1, (6)
C
45
u
1,33
+C
44
u
2,33
+C
34
u
3,33
=ρii
2, (7)
C
55
u
1,33
+C
34
u
2,33
+C
33
u
3,33
=ρii
3, (8)
where all quantities are now referred to the rotated axes.
Substitution of the plane wave solution (5) into Eqs. (6)-(8) yields as expressed in Eq. (9):
[M]{A}={0}, (9)
where M is a symmetric, positive-definite (3×3) matrix, and its elements are given by Eqs. (10)-(15)
M(1,1)=C55−ρV2, (10)
M(1,2)=C45, (11)
M(1,3)=C35, (12)
M(2,2)=C44−ρV2, (13)
M(2,3)=C34, (14)
M(3,3)=C33−ρV2, (15)
and the components A1, A2, and A3 of the polarization vector along the X1, X2, and X3-directions, respectively, are expressed in Eq. (16):
{A}=└A1A2A3┘T. (16)
The three plane wave velocities may be obtained by setting the determinant of the matrix M=0. For each of the plane wave velocities, the amplitude ratios defining the polarization vector may be solved for from Eq. (9).
Referring to
Ignoring the borehole problem for the moment, one may consider the propagation of plane waves in a few TI-formations. Assume the TI-symmetry axis to be parallel to the X3-axis as shown in
The TI-elastic constants with the X3-axis parallel to the symmetry axis takes the form as expressed in Eq. (17):
where C66=(C11−C12)/2, and we have used Voigt's compressed notation that combines the two indices into one using the following transformation: (11→1), (22→2), (33→3), (23→4), (31→5), and (12→6). Thus, for example, C1212→C66.
Table 1 contains the five independent TI-elastic constants for three different formations. These TI-elastic constants together with mass density are sufficient to calculate the three plane wave velocities or slownesses for propagation along any direction with respect to the TI-symmetry axis. Sometimes it may be convenient to work with the two moduli C33 and C44, and three dimensionless anisotropy parameters, ε, η, and γ, each of which vanishes when the medium is isotropic as expressed in Eq. (18):
where ε, γ, and δ are widely used Thomsen parameters for characterizing TI formations. Transverse isotropy may be caused by the existence of finely layered isotropic constituents. It has been shown that ε>δ, for TI media formed from laminated isotropic materials. δ provides a measure of the variation of the P-wave velocity with the phase angle and may be expressed as a function of the stiffness coefficients as shown in Eq. (18). δ relates vertical velocity to VNMO in seismic imaging and describes near offset variation. δ may be useful for time-to-depth conversion. η is a measure of an ellipticity for polar anisotropy and relates VNMO to horizontal velocity.
In
These results may be useful to identify potential errors in the input data to the estimation of TI-elastic constants. For example, if the measured dipole shear slownesses (or velocities) are nearly the same and the relative dip with respect to the borehole axis is about 60 degrees, it is a clear indication that the input data is NOT consistent with a TI-model. One cannot expect the SH and qSV-wave velocities to be nearly the same for propagation direction of 60 degrees from the TI-symmetry axis. Insofar as the cross-dipole shear velocities are reliable and robust measurements, a more likely source of error is in the estimate of relative dip angle that might have been caused by uncertainties in the dip azimuth and dip angle.
In the past, Thomsen parameters were derived from two or more boreholes with different well deviations.
Other approaches have included using a vertical well and a deviated building angle into a horizontal well to derive the Thomsen Parameters. However, previous methods are based on a weak anisotropy approximation.
In the scenario presented in
Estimation of TI-Elastic Constants from Sonic Data
One or more embodiments of the present disclosure describe methods for estimating five TI (Transversely-Isotropic) elastic constants of strongly anisotropic shale formations using borehole sonic data. Borehole sonic data include refracted and reflected plane wave arrivals together with guided modes, such as the Stoneley and cross-dipole flexural waves. A major distinguishing feature of one or more embodiments of the present disclosure is that the proposed workflows are not limited to a weak anisotropy approximation (where the Thomsen parameters may be assumed to be less than unity), as is the case in previous methods. A weak anisotropy approximation may be applied when the Thomsen parameters are less than a value other than unity, for example, 0.5.
One or more embodiments of the present disclosure may provide workflows for estimating all five TI-elastic constants using borehole sonic data acquired from (a) vertical and deviated boreholes; (b) horizontal and deviated boreholes; (c) two boreholes with different deviations; and (d) vertical, horizontal and deviated.
One or more embodiments of the present disclosure may describe a workflow to estimate all five TI-elastic constants using borehole sonic data from a horizontal borehole together with reflection data from a nearby horizontal limestone (or any other stiff stringer) layer. Other examples of stiff stringers include dolomite and anhydrite. In one or more embodiments, the stiff stringer may be located 1 to 4 feet away from the borehole wall. Processing of sonic data from a horizontal borehole parallel to the X1-axis, yields three of the five TI-elastic constants (C11, C55, and C66), whereas the reflection data provide estimates of the remaining two TI-elastic constants (C33 and C13) together with the distance of the reflector from the borehole surface.
One or more embodiments of the present disclosure may be based on analyzing both refracted and reflected quasi-compressional waves from a nearby horizontal limestone embedded in a thick shale formation. The transmitter and an array of receivers may be placed in a horizontal borehole in the shale formation. Refracted quasi-compressional arrivals from both the shale and proximate stiff, e.g., limestone, layers are obtained from the recorded waveforms. A limestone layer is an example of a proximate stiff layer. In the present disclosure, a limestone layer is understood to be representative of a proximate layer and that other types of formation including dolomite and anhydrite may be substituted. Below are four observations that may be described by four equations to be solved for four unknowns:
In one or more embodiments, a formation layer stiffer than the formation in which the horizontal borehole is located may be used in place of the limestone layer. This layer may be referred to as a proximate stiff layer. The aforementioned four equations may be solved for the unknowns D, θ1, VqP (θ1), and axial offsets Zshale in the shale formation traveled by the refracted wave in the limestone layer. Given a known value of reflector distance D, estimate VqPshale (θ) in shale from the reflected wave arrivals for a series of T-R spacings from 1 to 7 ft as shown in Table 6. Estimates of VqPshale (θ) in shale for multiple propagation directions θ from the TI-symmetry (X3-) axis may then be used to calculate the two Thomsen parameters ε and δ. The Thomsen parameter gamma may be estimated from the difference between the fast and slow shear slownesses from cross-dipole sonic logging data acquired from a horizontal borehole parallel to the X1-axis.
Most formations exhibit some degree of anisotropy. AVO analysis may require some combinations of formation TI-elastic constants. Some of these TI-elastic constants may be obtained from the borehole sonic measurements, others may be obtained from borehole seismic measurements, such as walk-away VSPs. TI-elastic constants that may be obtained from the borehole sonic measurements are the three formation shear moduli and a quasi-compressional modulus.
The formation shear anisotropy may be caused by aligned fractures, thin beddings or microlayering in shales. This type of anisotropy is called formation intrinsic anisotropy. Non-hydrostatic prestresses in a formation may introduce stress-induced anisotropy. Strictly speaking, stress-induced anisotropy may be properly described by equations of motion for small dynamic fields superposed on a static bias that may be derived from nonlinear continuum mechanics. Based on this theory, it has been demonstrated that a dipole dispersion crossover may be an indicator of stress-induced anisotropy dominating any intrinsic anisotropy that may also be present.
Consider the special case of a borehole with its axis parallel to the X3-axis of an orthorhombic formation. The elastic constants referenced to the borehole axes for an orthorhombic formation takes the form expressed in Eq. (19):
where the 9 independent elastic moduli are C11, C12, C13, C22, C23, C33, C44, C55, and C66.
Referring to
A dipole source in such a borehole may generate two principal flexural waves. Low-frequency asymptotes of these two flexural dispersions yield the two shear wave velocities that provide two of the three shear moduli of the formation. As indicated in
Sonic data acquired in deviated boreholes yield formation elastic constants referred to the borehole measurement axes. These elastic constants may be transformed to corresponding TI-elastic constants referred to the earth anisotropy axes. The transformed TI-elastic constants may then be used for a proper interpretation of rock lithology.
Sonic data acquired in boreholes with dipping beds would also yield apparent elastic constants referred to the borehole measurement axes. Measurement of formation true dip together with well deviation yields the relative dip with respect to the borehole axes. Knowing the relative dip with respect to the borehole axis, then enables one to determine real TI-elastic constants referred to the earth anisotropic axes.
If the borehole makes an angle θ with respect to the TI-symmetry axis, the quasi-compressional headwave velocity VqP, the pure shear wave velocity VSH, and the quasi-shear wave velocity VqSV may be obtained from the solution of the following Eqs. (20):
C
3jk3
|
u
k,33
=ρii
j, (20)
where C|ijkl denote rotated TI-elastic constants referred to the deviated borehole axis making an angle θ with respect to the TI-symmetry X3-axis, uj is the particle displacement associated with the plane wave propagation, and ρ is the mass density of the propagating medium. The solution for plane wave propagation along the deviated borehole axis may be obtained from the following matrix equation (21):
where C|34=C|45=0, for a TI-formation. The three plane wave velocities may be obtained from the determinant of the coefficient matrix that must vanish. Two of the eigenvalues may be solved for from the following quadratic equation in X as expressed in Eq. (22):
λ2−(C|3+C|55)λ+(C|33C|55−C35|2)=0, (22)
where the two roots of this quadratic equation may be solved from the following Eqs. (23):
The three eigenvalues corresponding to the three plane wave velocities in Eq. (21) may be given by Eqs. (24):
λ1=ρVqP2,
λ2=ρVqSV2,
λ3=ρVSH2=C44|=C44|=C44 cos2θ+C66 sin2θ. (24)
When estimating the TI-elastic constants from the plane wave velocities, it may be useful to relate the rotated TI-elastic constants to the TI-elastic constants following orthogonal transformation relations for a 4-rank tensor Cijkl. Rotated TI-elastic constants in the Voigt's compressed notation may be expressed in terms of TI-elastic constants as shown below as expressed in Eqs. (25):
The sum and product of the two eigenvalues of Eq. (21) may be given by the following Eq. (26)
These equations provide closed-form expressions relating the five TI-elastic constants to measured qP, qSV, and SH wave velocities along a deviated borehole that makes an angle θ with respect to the TI-symmetry axis. Insofar as the SH-wave is a pure shear wave, and qSV-wave is a quasi-shear wave that also has an axial component, one may expect the receiver amplitude of the SH-wave to be larger than that of the qSV-wave as recorded by the hydrophones on the borehole axis.
TI-Elastic Constants from Wells with Different Deviations in Strongly Anisotropic Formations
One or more embodiments of the present disclosure may include multiple workflows to estimate all five TI-elastic constants using four different combinations of measured sonic velocities in boreholes with different deviations: (a) vertical and deviated; (b) horizontal and deviated; (c) two different deviations; and (d) vertical, horizontal and deviated.
While steps in one or more embodiments of the present disclosure, may be presented in a particular order, it is understood that other ordering of steps may be possible.
(a) Five TI-Elastic Constants from a Vertical and a Deviated Borehole
where, as expressed in Eqs. (28):
Eqs. (27) together with (28) may be substituted into (23) to solve for C13 when C11, C33, and C55 are known from other sources.
Compressional and shear wave velocities along a vertical borehole parallel to the TI-symmetry axis yield the compressional modulus C33 and shear modulus C44(=C55) as shown below in Eqs. (29) and seen in steps 1410, 1415, and 1420:
C
33
=ρV
P
2,
C
44
=C
55
=ρV
SH
2
=ρV
SV
2, (29)
where the compressional wave velocity VP may be obtained from the DTCo log, and the cross-dipole shear logs may provide VSH and/or VSV.
(2) Deviated Borehole with Dip θ Relative to the TI-Symmetry X3-Axis
Next one may write rotated TI-elastic constants referred to the deviated borehole axes (denoted by primed superscript) that may be related to the measured qP, qSV, and SH wave velocities. These relations are given by the following Eqs. (30):
where, as expressed in Eqs. (31):
Since (a2+a5=0), one may solve for C11 from the following Eq. (32) that has been derived from Eq. (26) as seen in step 1425:
At this point, we have already solved for C33, C55, and C11. Next one may estimate C66 from the following Eq. (33) obtained from Eq. (24) as seen in step 1430:
Finally, one may solve for C13 from the following quadratic Eq. (34) as seen in step 1435. Eq. (34) has been obtained from Eq. (23) after substituting for rotated TI-elastic constants in terms of TI-elastic constants as shown in Eqs. (27) and (28). This quadratic equation (34) does not require any lengthy search for a minima of a cost function
(ac−e2)x2+[(ad+bc−2ef)−λ(a+c)]x+(bd−f2)+λ2−λ(b+d)=0, (34)
where, as expressed in Eqs. (35):
One or more embodiments of a method obtain the five TI-elastic constants from sonic data acquired in a vertical and a deviated borehole.
(b) Five TI-Elastic Constants from a Horizontal and a Deviated Borehole
Referring to
Consider a horizontal borehole parallel to the X1-axis, and perpendicular to the TI-symmetry X3-axis. Compressional VP, and cross-dipole shear wave velocities VSH and VSV yield three of the five TI-elastic constants as given by the following three Eqs. (36) as seen in steps 1460, 1465, and 1470:
C
11
=ρV
P
2,
C
55
=ρV
qSV
2,
C
66
=ρV
SH
2 (36)
2. Deviated Borehole with Dip θ Relative to the TI-Symmetry X3-Axis
Next one may invert the quasi-compressional and two shear wave velocities measured with respect to the deviated borehole axis to estimate the compressional modulus C33 and C13. To this end, one may write the rotated TI-elastic constants referred to the deviated borehole axes (denoted by primed superscript) that can be related to the measured qP, qSV, and SH wave velocities. These relations may be given by the following Eqs. (37):
where, as expressed in Eqs. (38):
One may now solve for C33 from the measured quasi-compressional qP and quasi-shear qSV wave velocities parallel to the deviated borehole axis from the following Eq. (39) obtained from Eq. (26) and seen in step 1475:
Since C55 and C66 may be known from the cross-dipole shear wave velocities from a horizontal borehole, and VSH(θ) is measured with respect to the deviated borehole axis, one may use the following equation as a consistency check as shown in step 1480. VSH(θ) explicitly recognizes that VSH may be a function of propagation direction measured from the TI-symmetry axis. The propagation direction is the same as the borehole axis orientation from the TI-symmetry axis. This equation may also be used to confirm that qSV and SH wave velocities measured from a deviated borehole have been properly labeled using the following Eq. (40) re-written from Eq. (24)
ρVSH(θ)2=C55 cos2θ+C66 sin2θ. (40)
Finally, one may solve for C13 from the following quadratic equation (41) that does not require any lengthy search for a minima of a cost function as shown in step 1485:
(ac−e2)x2+[(ad+bc−2ef)−λ(a+c)]x+(bd−f2)+λ2−λ(b+d)=0, (41)
where, as expressed in Eqs. (42):
Eq. (41) has been re-written from Eq. (23) in terms of new variables that enables a solution of C13 from a quadratic equation.
(c) Five TI-Elastic Constants from Three Sonic Velocities in Two Deviated Boreholes
When one has quasi-compressional VqP, quasi-shear VqSV, and shear VSH velocities in two wells with different deviations or relative dips θ1 and θ2 in the same lithology interval, one may compute all five TI-elastic constants even in the absence of Stoneley data. An embodiment in accordance with the present disclosure may be seen in
One may then process the monopole refracted waveforms to output velocities VqP(θ1) and VqP(θ2) as seen in step 1510. One may process the dipole waveforms to estimate the SH-wave velocities VSH(θ1) and VSH(θ2) as seen in step 1515. Further, one may process the dipole waveforms to estimate the qSV wave velocities VqSV(θ1) and VqSV(θ2) as seen in step 1520. If the borehole makes an angle θ1 and θ2 with respect to the TI-symmetry axis, the shear (SH) velocity VSH(θ1) and VSH(θ2) are related to the TI-elastic constants C44 and C66 by the following Eqs. (43):
ρ1VSH(θ1)2=C44 cos2θ1+C66 sin2θ1,
ρ2VSH(θ2)2=C44 cos2θ2+C66 sin2θ2. (43)
One may solve these two simultaneous equations for C66 and C44 and express them by the following two Eqs. (44) and seen in step 1525:
Solve for C33 and C11:
Since the shear modulus C44 or C55 is now known, one may use the following Eq. (45) valid for the two borehole deviations of θ=θ1 or θ2, with respect to the borehole axis to compute the TI-elastic constants C11 and C33.
We may form the following two simultaneous Eqs. (46) in C11 and C33
d
1
C
11
+d
2
C
33
=d
3,
d
4
C
11
+d
5
C
33
=d
6, (46)
and the solution for C33 and C11 may be expressed as shown below in Eqs. (47) as seen in step 1530:
where, as expressed in Eqs. (48):
Finally, one may solve for C13 from the following quadratic Eq. (49) that does not require any lengthy search for a minima of a cost function as seen in step 1535:
(ac−e2)x2+[(ad+bc−2ef)−λ(a+c)]x+(bd−f2)+λ2−λ(b+d)=0, (49)
where, as expressed in Eqs. (50):
Eq. (49) has been re-written from Eq. (23) in terms of new variables that provides a closed-form solution of C13 from a quadratic equation.
(d) Five TI-Elastic Constants from a Vertical, a Horizontal and a Deviated Borehole
In one or more embodiments, the five TI-elastic constants may be determined from a vertical, a horizontal, and a deviated borehole. An embodiment in accordance with the present disclosure may be seen in
Below are two different algorithms that may be used to estimate the TI-elastic constant C13 from the deviated borehole sonic data:
There are two different ways to estimate C13 when the other four TI-elastic constants are known from the vertical and horizontal borehole sections in the same lithology interval. Next we describe two different quadratic equations in C13. The first quadratic equation requires to input both the VqP and VqSV velocities.
a. Recall that One May Express the Product of the Two Eigenvalues as Given by Eq. (51):
λ1λ2=(C33|C55|−C35|2)=(ρVqP2)(ρVqSV2), (51)
where the rotated C|33, C|55, and C|35 must now be expressed in terms of the five TI-elastic constants and the relative dip of the deviated borehole axis.
Substituting for the rotated C|33, C|55, and C|35 in terms of the TI-elastic constants and relative dip θ from the TI-symmetry axis, as shown in step 1875, one may solve for the remaining unknown C13 from the following quadratic equation (52):
(d1d3−d52)x2+(d1d4+d2d3−2d5d6)x+d2d4−d62−ρ2VP(θ)2VSV(θ)2=0, (52)
where, as expressed in Eqs. (53):
Solve the above quadratic equation in C13 using both the qP and qSV wave velocities measured along the deviated borehole axis.
(b) Alternatively, as shown in step 1880, one may also solve for C13 from a quadratic equation (54) shown below after the other four TI-elastic constants (C11, C33, C55, and C66) are known in the lithology interval of interest.
(ac−e2)x2+[(ad+bc−2ef)−λ(a+c)]x+(bd−f2)+λ2−λ(b+d)=0, (54)
where, as expressed in Eqs. (55):
One may solve the above quadratic equation in C13 using either qP or qSV wave velocity measured along the deviated borehole axis. One way to estimate C13 may be to use only the qSV wave velocity from the deviated borehole section to minimize the tool eccentering effects on the quasi-compressional qP-wave velocity.
Thus, shown in steps 1830, 1855, 1885, and 1890, one may obtain all five TI-elastic constants in a depth interval with a reasonably uniform lithology from sonic data acquired in two boreholes with different relative dips caused by changes in the borehole deviations. This procedure may be used in the absence of any Stoneley data that requires an accurate estimate of mud compressional wave slowness (DTmud).
At this point it may be instructive to review plane wave phase velocity variations as a function of propagation direction θ from the TI-symmetry axis. This angle θ from the symmetry axis is the same as the relative dip of formation bedding from the borehole axis.
Both the monopole and dipole sonic waveforms recorded at an array of receivers may be processed by a modified matrix pencil algorithm that isolates non-dispersive and dispersive arrivals in the wave train. Sonic measurements from a borehole parallel to the X3-axis provide four different slownesses corresponding to: compressional modulus (C33), fast and slow dipole shear moduli (C44 and C55) and Stoneley horizontal shear modulus (C66) that may help to estimate three formation shear moduli and a compressional modulus of an orthorhombic formation using the far-field sonic velocities.
Differences between the three shear moduli may help to determine the type of anisotropy. For example, in a reservoir in the presence of horizontal fluid mobility, C66 obtained by Stoneley may be somewhat smaller than C44 from dipole. In a shaly formation, C66 is larger than C44. In addition, C66 smaller than C44 in a sandy formation might be also caused by vertical stress being larger than the horizontal stress.
Theoretical validation results are presented for only moderately anisotropic Bakken shale formation. Nevertheless, we have obtained similar validation results for Austin chalk and Cotton valley shale formations as well. These formations are less anisotropic than Bakken shale and weak anisotropy approximation may be also valid for such formations.
Table 2 contains phase velocities of the qP, qSV, and SH waves as a function of propagation direction, i.e., well deviation, from the TI-symmetry X3-axis. These velocities have been obtained from the three eigenvalues of Eq. (9).
Table 3 contains a summary of comparison of the inverted TI-elastic constants using phase velocities of the qP, qSV, and SH waves from two boreholes with different deviations. These synthetic velocities have been obtained from the three eigenvalues of Eq. (9), and are listed in Table 2. Excellent agreement between the inverted and actual TI-elastic constants confirms the validity of the proposed workflow.
Next, we compare inverted TI-elastic constants with the actual ones using synthetic phase velocities from a vertical (deviation=0 degree) and deviated boreholes. All different combinations of vertical and deviated boreholes yield TI-elastic constants remarkably close to the actual TI-elastic constants as shown in Table 4a. Hence, we have again validated the proposed workflow of inverting velocity data from a vertical and a deviated borehole.
In another illustrative example, we compare inverted TI-elastic constants with the actual ones using synthetic phase velocities from a horizontal (deviation=90 degree) and deviated boreholes. All different combinations of horizontal and deviated boreholes yield TI-elastic constants remarkably close to the actual TI-elastic constants as shown in Table 4b. Hence, we have again validated the proposed workflow of inverting velocity data from horizontal and deviated boreholes.
To invert for all five TI-elastic constants, it may be important to distinguish between the SH-wave and qSV-wave velocities measured by the cross-dipole tool. Depending upon the borehole deviation or relative dip with respect to the borehole axis, either the SH-wave or qSV-wave might exhibit larger velocity than the other. Insofar as the SH-wave is a pure shear wave, and qSV-wave is a quasi-shear wave that also has an axial component, one may expect the receiver amplitude of the SH-wave to be larger than that of the qSV-wave as recorded by the hydrophones on the borehole axis. In addition, synthetic plane wave velocities as a function of borehole deviation may also help in the identification of the SH-wave and qSV-wave velocities after processing the cross-dipole data.
The phase correspondence rule as seen in Table 5 states that plane wave velocities measured using a sonic tool in a deviated borehole are phase velocities with the borehole axis aligned with the phase direction of the propagating wave-front.
TI-Elastic Constants from a Single Horizontal Well Data
Production of hydrocarbons from organic shale-gas reservoirs requires horizontal well drilling that can extend to more than 10,000 feet from the vertical pilot well. Such large horizontal distances from the vertical pilot well may lead to challenges in combining sonic data from well trajectories with different deviations to enable inversion for all five TI-elastic constants within a homogeneous lithology. Optimal completion of such lateral producer wells may require estimates of all five TI-elastic constants from a single horizontal well sonic data. Inversion for the vertical compressional modulus C33 and to a lesser degree the modulus C13 from sonic data acquired solely from a single horizontal well remains a challenge in the existing workflow. To overcome these limitations, we propose a new workflow that combines reflection data from a nearby horizontal proximate stiff layer, for example, a limestone (or stiff calcite) layer, together with a standard sonic logging to output both C33 and C13 with enhanced accuracy and reliability. This workflow may include the following steps:
The incident angle θ1 of qP-wave may be described by the following Eq. (56):
where the angle θ denotes θ1, θ2, θ3 for the corresponding offsets Z(=Z1, Z2, and Z3), respectively. The travel-time for a chosen ray path may be expressed by Eq. (57):
where VqP (θ) denotes the velocity of qP-waves propagating at an angle θ from the TI-symmetry axis. This velocity VqP (θ) may be expressed in terms of the rotated C33| (θ) as expressed by the following Eq. (58):
where ρ is the mass density of the anisotropic formation and, as expressed in Eq. (59):
ρVqP2(θ)=C33|(θ)=C33[1+2ε sin4θ+2δ sin2θ cos2θ], (59)
based on a weak anisotropy approximation, whereby Thomsen parameters are given by Eq. (60):
Note that the moduli C11, C55, and C66 may be directly estimated from the refracted quasi-compressional, the slow and fast dipole shear wave velocities, respectively, from a sonic tool in a horizontal borehole parallel to the X1-axis. The two remaining TI-elastic constants to be estimated are C33 and C13.
The exact equation for VqP (θ) may be obtained from the solution of the Kelvin-Christoffel equations in the presence of strong anisotropy and may be expressed as Eq. (61):
where, as expressed in Eqs. (62)-(64):
C
33
|(θ)=b1C33+b2C13+b3,
b
1=cos4θ,
b
2=2 sin2θ cos2θ,
b
3
=C
11 sin4θ+C55 sin2 2θ, (62)
C
55
|(θ)=b4C33+b5C13+b6,
b
4=(1−cos 4θ)/8,
b
5=−(sin2 2θ)/2,
b
6=[C11 sin2 2θ+2C55(1+cos 4θ)]/4, (63)
C
35
|(θ)=b7C33+b8C13+b9,
b
7=−sin 2θ(1−cos 4θ)/4,
b
8=(sin 2 θ cos 2∂4)/2,
b
9
=C
11(sin2θ sin 2θ)/2+C55 sin 2θ cos 2θ. (64)
Corresponding to the three ray paths depicted in
V
qP
2(θ1)t12=Z12+4D2, (65)
V
qP
2(θ2)t22=Z22+4D2, (66)
V
qP
2(θ3)t32=Z32+4D2, (67)
Note that VqP(θ) may be obtained from Eq. (58) using a weak anisotropy approximation, or from Eq. (61) that represents the exact solution for quasi-P wave velocity for propagation at an angle θ from the TI-symmetry axis. Eq. (61) is the exact solution of the Kelvin-Christoffel equations for plane waves in anisotropic formations.
If C13 is known from the inversion of dipole flexural dispersion, the workflow would reduce to the determination of two unknowns C33 and the reflector distance D from the reflector layer, for example a limestone layer, and the borehole surface. Once all five TI-elastic constants have been determined from a single horizontal well data, it may be straight-forward to calculate three Thomsen parameters that may then be used in seismic interpretation of AVO as well as geomechanical analysis of organic shale reservoir in terms of anisotropic mechanical properties.
The travel-times t1, t2, and t3 may be estimated from a standard STC processing of monopole (or dipole) waveforms using three different sub-arrays of receivers. The mid-point of the sub-array provides an effective offset of the received waveforms from the source that may then be used in the three travel-time equations. Note that there are two workflows based on whether the expression for the qP-wave velocity VqP(θ) may be obtained from a weak anisotropy approximation or an exact solution of the Kelvin-Christoffel equations.
Referring to
Monopole and cross-dipole waveforms may be recorded at an array of receivers in a horizontal borehole parallel to the X1-axis (step 1605). The monopole refracted headwaves may be processed to output monopole compressional modulus C11 (step 1610), the fast-dipole waveforms may be processed to estimate shear modulus C66 (step 1615), and the slow-dipole waveforms may be processed to estimate shear modulus C55 (step 1620). The reflected quasi-compressional waveforms may be recorded at multiple sub-arrays of receivers in the horizontal borehole parallel to the X1-axis (step 1625). Process three subarrays of four receivers to estimate arrival times t1, t2, and t3 of the reflected quasi-compressional wave packets using the STC algorithm (step 1630). Measure the effective offsets Z1, Z2, and Z3 of these three sub-arrays from the source (step 1635) where the effective offsets are defined by the midpoints of the sub-arrays from the source S. Estimate directions of the ray-paths θ1, θ2, and θ3 from the vertical TI-symmetry axis in terms of reflector distance D and sub-array offsets (step 1640). Solve the three travel-time equations for the unknowns C33, C13, and reflector distance D (step 1645) where inputs are C11, C55, and C66 from the horizontal well sonic logging. Reflection data analysis provides estimates of arrival times t1, t2, and t3; sub-array offsets z1, z2, and z3; and ray-path directions θ1, θ2, and θ3. The five TI-elastic constants and reflector distance D may be output based on the weak anisotropy assumption for the quasi-compressional wave velocity VqP (θ) (step 1650). As an alternative to step 1650, the five TI-elastic constants and reflector distance D may be output based on the exact solution for the quasi-compressional wave velocity VqP (θ) (step 1660). When step 1660 is taken rather than step 1650, i.e., when the exact solution for the compressional wave velocity is used rather than the weak anisotropy approximation, the result is valid for all formation anisotropy, including strong anisotropy.
TI-Elastic Constants from a Single Horizontal Well Data
One or more embodiments of the present disclosure may be based on analyzing both refracted and reflected quasi-compressional waves from a nearby horizontal limestone embedded in a thick shale formation. The transmitter and an array of receivers may be placed in a horizontal borehole in the shale formation. Refracted quasi-compressional arrivals from both the shale and limestone layers may be obtained from the recorded waveforms. Below are four observations that may be described by four equations to be solved for four unknowns:
Z=Z
limestone+√{square root over (Zshale2+4D2)}, (68)
where D denotes reflector distance from the borehole surface to the proximate stiff layer, and Zshale includes two axial offsets in the shale formation and is given by Eq. (69):
Z
shale
=Z
TR
Z
limestone. (69)
The ray-path geometry of refracted wave in the limestone layer yields, as expressed in Eq. (70):
where θ1 is the incidence angle of quasi-compressional wave in the shale formation.
From Snell's law, the incidence angle θ1 for a critically refracted headwaves in the limestone layer is given by Eq. (71):
where VPlimestone may be assumed to be known from the limestone quasi-compressional arrival.
The limestone quasi-compressional arrival time t2 may be determined from the STC processing of monopole waveforms and may be given by Eq. (72):
The time offset t1 of the limestone arrival from its T-R line may be obtained from the STC-plot and may be given by Eq. (73):
Note that the refracted quasi-compressional shale arrival provides an estimate of the VqPshale (90°) that yields the quasi-compressional modulus C11 for the shale formation. Solve the above four equations for the unknowns D, θ1, VqPshale(θ1), and Zshale from Eqs. (70), (71), (72) and (73).
By examining both the reflected and refracted sonic quasi-compressional and shear waves from tight formations such as limestone stringers within approximately 4 feet from a horizontal well in a TIV shale, one or more embodiments may describe a method to solve for the three Thomsen parameters, and in particular, C33 and C13 based on the geometry of the ray-paths and the spacing of the transmitter and receivers of sonic logging tools.
In the STC plot of
The sonic velocities for VqP (θ) may be derived if the angle (θ) and velocity for the reflected quasi-compressional wave is known. If the reflector distance D is known, the velocity associated with each T-R pair may be determined by the arrival time of the reflected quasi-compressional wave at each receiver. Plotting the velocity of each T-R pair versus the angle (as shown in Table 6) and using the expressions below the Thomsen parameters may be determined.
The quasi-P and quasi-S wave velocities may be expressed in terms of Thomsen parameters and propagation direction from the TI-symmetry axis as shown below in Eqs. (74):
where, as expressed in Eqs. (75):
If the limestone layer is sufficiently far way (about 3 to 4 ft from the borehole surface), the velocity of the first quasi-compressional arrival is approximately equal to VP0 that provides a direct estimate of quasi-compressional modulus C33 and Thomsen parameter δ.
In addition, the quasi-compressional wave velocity for rays at 45 degrees from the TI-symmetry axis may be determined from the T-R pair as indicated in Table 6. When VP(Θ=45 degrees) is known from such a T-R pair, the TI-elastic constant C13 may be determined from the following Eq. (76):
where C11 and C44=C55 are determined from the sonic data acquired along a horizontal borehole parallel to the X1-axis.
Now that C13 and C33 are determined, and C11, C44, and C66 are known from the horizontal well sonic data, the three Thomsen parameters may be obtained from Eq. (60).
The above method may be valid when the horizontal well deviation is parallel to the shale laminations and the dense limestone layer or some other proximate stiff layer. If the proximate stiff layer is not parallel to the well deviation the STC processing for the refracted P wave should be done using multi-shot processing of sub-arrays and the distance of the STC peak for each subarray should increase or decrease with the T-R spacing based on the apparent dip of the proximate stiff layer. Once the apparent dip is known, the analysis described above for the reflected P arrivals may be corrected based on the cosine of the apparent dip angle.
Although only a few example embodiments have been described in detail above, those skilled in the art will readily appreciate that many modifications are possible in the example embodiments without materially departing from this disclosure. Accordingly, all such modifications are intended to be included within the scope of this disclosure as defined in the following claims. In the claims, means-plus-function clauses are intended to cover the structures described herein as performing the recited function and not only structural equivalents, but also equivalent structures. Thus, although a nail and a screw may not be structural equivalents in that a nail employs a cylindrical surface to secure wooden parts together, whereas a screw employs a helical surface, in the environment of fastening wooden parts, a nail and a screw may be equivalent structures. It is the express intention of the applicant not to invoke 35 U.S.C. § 112(f) for any limitations of any of the claims herein, except for those in which the claim expressly uses the words ‘means for’ together with an associated function.