Sedimentary rocks and man-made materials like concrete may be described as a network of mesoscopic-sized “hard” elements (e.g., grains with characteristic lengths ranging from tens to hundreds of microns) embedded in a “soft” bond system (e.g., cement between grains, pore space, fluid). Such systems belong to a wider class of materials referred to as Nonlinear Mesoscopic Elastic Materials (NMEMs). The microscopic-sized imperfections at the interfaces between “hard” and “soft” subsystems are believed to be responsible for a number of interesting properties related to nonlinear and nonequilibrium dynamics, including the dependence of elastic parameters and attenuation on strain amplitude, slow dynamics, and hysteresis with end-point memory. Understanding and predicting these properties is basic for numerous applications including oil exploration.
Wellbore ‘blowout’ is one of the costliest and dangerous issues faced by drilling companies today. When high pressure zones are breached during drilling operations the hydrocarbon fluids travel up the well at a high rate, forcing out the drill string and creating what is known as a blowout. The Deep Water Horizon event that took place off the coast of Texas in 2011 is an example of the consequences of a blowout-injury, death and an environmental disaster, the ecological impact being severe, profound, and lasting. Overpressures can be generated by many mechanisms including compaction, disequilibrium (under-compaction), hydrocarbon generation and gas cracking, aquathermal expansion, tectonic compression (lateral stress), mineral transformations (for example, illitization), and osmosis, hydraulic head and hydrocarbon buoyancy. It has been reported that in the U.S., there is one blowout incident for every 285 wells drilled.
Successful blowout preventers (BOPs) have been developed. A BOP valve affixed to the wellhead may be closed in the event of drilling into a high pressure zone, and the well fluids contained. However, despite the control brought by the advent of the BOP, blowouts are still a source of significant damage and cost.
Knowledge of pore pressure in a formation is valuable for planning drilling operations and for geochemical and geological analyses. Pore pressures are the fluid pressures in the pore spaces in the porous formations. The pore pressure gradient is used in drilling for determining mud weight, which is selected based on pore pressure gradient, wellbore stability and fracture gradient prior to setting and cementing a casing. The drilling fluid is applied in the form of mud pressure to support the wellbore walls for preventing influx and wellbore collapse during drilling.
To achieve the purposes of embodiments of the present invention, as embodied and broadly described herein, the method for measuring pore pressure in a formation, hereof, includes: generating a pulsed sinusoidal acoustic signal having a chosen frequency from a first transceiver disposed in a borehole in the formation; receiving the acoustic signal on at least one second transceiver disposed in the borehole; time reversing the received signal; transmitting the time-reversed signals from the at least one second transceiver, whereby the time-reversed acoustic signals form a focal volume centered on the first transceiver; receiving second and third harmonics of the chosen frequency generated in the focal volume on the first transceiver, the harmonic signals having an amplitude; and monitoring the amplitude of the received harmonic signals.
In another aspect of embodiments of the present invention and in accordance with its purposes the apparatus for measuring pore pressure in a formation, hereof, includes: a first signal generator for generating a pulsed sinusoidal signal having a chosen frequency; a first transceiver disposed in a borehole in the formation for receiving the signal from the first signal generator, and transmitting an acoustic signal; at least one second transceiver disposed in the borehole for receiving the transmitted acoustic signal and generating a first electrical signal therefrom; a processor for receiving the first electrical signal and time reversing the received signal; at least one second signal generator for receiving the time-reversed electrical signal, generating a second acoustic signal therefrom, and directing the second acoustic signal onto the at least one second transceiver, such that the second acoustic signal is transmitted; whereby the time-reversed acoustic signal forms a focal volume centered on the first transceiver, second and third harmonics of the chosen frequency are generated in the formation and received by said first transceiver, producing a second electrical signal having an amplitude, and the amplitude of the second electrical signal is monitored by the processor.
In yet another aspect of embodiments of the present invention and in accordance with its purposes the method for measuring pore pressure in a formation through a borehole having a metal casing, hereof, includes: generating a pulsed sinusoidal acoustic signal having a chosen frequency from a first transceiver disposed in the borehole; receiving acoustic signals on at least one second transceiver disposed in the borehole above the first transceiver; time reversing the received signals; transmitting the time-reversed signals with a selected intensity, whereby the time-reversed acoustic signals form a focal volume centered on the first transceiver; receiving second harmonics of the chosen frequency generated in the formation, on the first transceiver, the second harmonic signals having an amplitude; monitoring the amplitude of the received harmonic signals, whereby 13 is determined; receiving a second acoustic signal responsive to vibrational excitation in the focal volume on a third transceiver disposed in vibrational communication with the metal casing; varying the intensity of the transmitted time-reversed acoustic signal; and measuring the time delay of the second acoustic signal relative to the time-reversed acoustic signal as a function of the intensity of the transmitted time-reversed acoustic signals; whereby a is determined.
In still another aspect of embodiments of the present invention and in accordance with its purposes the apparatus for measuring pore pressure in a formation through a borehole having a metal casing, hereof, includes: a first signal generator for providing a pulsed sinusoidal signal having a chosen frequency; a first transceiver disposed in the borehole in the formation for receiving the pulsed sinusoidal signal from the first signal generator, and transmitting an acoustic signal; at least one second transceiver disposed in the borehole for receiving the transmitted acoustic signal and generating a first electrical signal therefrom; a first processor for receiving the first electrical signal and time reversing the received electrical signal; at least one second signal generator for receiving the time-reversed electrical signal, generating a second electrical signal therefrom, and directing the second electrical signal onto the at least one second transceiver, such that a second acoustic signal having a selected intensity is transmitted; whereby the time-reversed acoustic signals form a focal volume centered on the first transceiver, the first receiver receiving second harmonics of the chosen frequency generated in the formation, the harmonic signals having an amplitude; a second processor for monitoring the amplitude of the received harmonic signals, whereby 13 is determined; a third transceiver disposed in the borehole in vibrational communication with the metal casing for measuring the time delay of the second acoustic signal relative to the time-reversed acoustic signal as a function of the selected intensity of the transmitted time-reversed acoustic signal; whereby a is determined.
Benefits and advantages of embodiments of the present invention include, but are not limited to, providing an apparatus and method for determining the existence of and the distance to a down hole over-pressured region in advance of a drilling bit, using a combination of time reversal and elastic nonlinearity.
The accompanying drawings, which are incorporated in and form a part of the specification, illustrate the embodiments of the present invention and, together with the description, serve to explain the principles of the invention. In the drawings:
As a result of the need for accurate pore pressure prediction for drilling operators to reduce borehole trouble time and avoid drilling incidents, oil companies and oil service companies have been seeking methods for detecting high pressures ahead drilling bits as they penetrate the earth, such that corrective action can be taken before the region is breached.
Overpressure rock has a signature elastic response that can be detected by combining Time Reversal techniques with Elastic Nonlinearity in a technique which is known as Time Reversal Nonlinear Elastic Wave Spectroscopy (TR NEWS). The nonlinear elastic wave response is directly related to the effective pressure (hydrostatic load minus the pore pressure). Time reversal is a method for focusing acoustic waves such that large wave amplitudes are obtained in a localized region of space. As a result of the large acoustic wave amplitudes at the focus and the nonlinearity of the material, harmonics may be generated (and sum and difference frequencies if two waves are present). These harmonic frequencies are detected at the focus and, as will be discussed in more detail below, changes in the amplitude of the detected harmonics indicate that high pressure may be present.
Nonlinear materials exhibit a nonlinear stress-strain relation which can be probed by acoustic waves, leading to pressure-specific acoustic signatures. Harmonics of the incident acoustic frequencies are created when the acoustic waves are focused. The effective pressure in a formation may be written as,
P
eff
=σ−bP (1)
where α is the confining pressure, P is the pore pressure, and b is the Biot coefficient (typically 0.4-0.9 in rock). The effective pressure can also be described by a nonlinear stress-strain relationship,
where K is the linear stiffness constant, ε is the strain, ΔE is the strain amplitude, {dot over (ε)} denotes the partial derivative with respect to time, sign is a function returning the sign (positive or negative) of the argument, β and δ are combinations of third- and fourth-order elastic constants representing the acoustoelasticity (quadratic and cubic classical nonlinearity), and the parameter α relates to the strength of the hysteresis, according to the Preisach-Mayergoyz model of elasticity. See, e.g., K. R. McCall et al., “A new theoretical paradigm to describe hysteresis, discrete memory and nonlinear elastic wave propagation in rock,” Nonlin. Proc. Geophys. 3, 89-101 (1996), R. A. Guyer et al., “Quantitative implementation of Preisach-Mayergoyz space to find static and dynamic elastic moduli in rock,” J. Geophys. Res. 102(B3), 5281-5293 (1997), and G. Douglas Meegan, Jr. et al., “Observations Of Nonlinear Elastic Wave Behavior In Sandstone,” J. Acoust. Soc. Am. 94, (1993) 3387-3391. Combining Eqs. (1) and (2) leads to an expression of the pore pressure as a function of confining pressure and nonlinear elastic parameters of the material,
The parameters α, β, and δ may be obtained from the time reversal signal, with α being obtained from the velocity change of the focused signal as a function of strain amplitude. The velocity change may be also measured using cross correlation or another standard technique on a low amplitude (linear) wave at the time reversal focus, and the progressive delays caused by using progressively larger amplitude excitation waves. Cross correlation is a commonly applied method for measuring time delays between a reference signal and a signal that has experienced a velocity change. β is obtained from the amplitude dependence of the second harmonic of a pulsed pure sinusoid or the amplitude dependence of sum (ω1+ω2) and difference (ω1−ω2) frequencies if two waves are employed. See, also, TenCate, J. A. et al. (1996) “Laboratory Study Of Linear And Nonlinear Elastic Pulse Propagation In Sandstone,” J. Acoust. Soc. Am. 100(3), 1383-1391. δ is obtained from the amplitude dependence of the third harmonic of the fundamental drive amplitude at small, but still nonlinear amplitudes and, in general, can be ignored. At larger amplitudes, however, α dominates and δ becomes overwhelmed and can be ignored.
α is given by:
where C0 is the linear velocity and C the perturbed velocity. The second derivative of u with respect to t is the particle acceleration measured in the frequency domain, f is the wave fundamental frequency, and ε is the strain measured at frequency fin the focal region as the signal source amplitude is increased. By plotting the change in wave speed as a function of strain, alpha can be obtained.
Alternatively, alpha can be obtained from the third harmonic amplitude also when wave amplitudes are large. In the following alpha, beta and delta are shown.
where L is the wavelength of the fundamental frequency divided by two, equivalent to the radius of the focal region, the second derivative of u with respect to time, 3f, is the third harmonic acceleration amplitude, the second derivative of u with respect to time, 2f, is the second harmonic acceleration amplitude, the second derivative of u with respect to time, 1f, is the fundamental harmonic acceleration amplitude, and ω=2πf, where f is the fundamental frequency.
Time reversal permits the generation of focused, intense (non-damaging) sound in a region to induce local nonlinearities if high pressure is present, by taking advantage of the above relation for u2f, thereby permitting detection and imaging of overpressure regions. As an example, waves may be introduced into a specimen using a piezoelectric transducer. The waves are recorded on another transducer located elsewhere on the sample surface. The recorded waves are then reversed in time, and emitted from the detecting transducers, where they follow their forward wave paths backwards-in-space, and coalesce, focusing at the original source transducer, since the elastic wave equation is symmetric with respect to time. That is, the wave equation may be evaluated either forward or backward in time, the physics being identical. Amplitudes at the time-reversed focus are large due to conservation of energy, since all of the energy contained in the long-duration scattered-signal is collapsed onto the focal point in space and time. Since wave amplitudes are largest at the focus, the local response may be nonlinear, but only at the focus.
Further, by measuring α and β for a formation using time reversal techniques, one can obtain accurate values for the pore pressure in a formation, using Equations 2 and 3, above. Among the uses for the gradient of the pore pressure are the prediction of gas/water contacts, which permit more accurate location of hydrocarbons in the formation.
Reference will now be made in detail to the present embodiments of the invention, examples of which are illustrated in the accompanying drawings. In the FIGURES, similar structure will be identified using identical reference characters. Turning now to
A schematic representation of an embodiment of transceiver mount 24 is shown in
Independently controlled low-frequency transceivers 22a mid-frequency transceivers 22b and high-frequency transceivers 22c controlled by digital synthesizers, 32, 34, and 36, respectively, which are directed by microcontroller and digital signal processor, 38, are affixed along mount 24 to provide the required excitation signals. Transducers vary in size and relative spacing depending on the center frequency of excitation signal that is intended to be generated. For low frequency excitation, large transducers are distributed over the entire length of the tool. For high frequency excitation, smaller transducers are centered with a smaller span around the point where focus should be achieved (at transceiver 12).
Source 12 generates a swept sine wave that encompasses frequencies fi . . . I that provide the spatial resolution λi . . . I of interest in a given group of strata. For example, given a typical formation velocity c of 2000 m/s, and a desired probe distance of I=10 m in advance of the drill bit, the time-reversed focal diameter would be d=20 m, and the center frequency would therefore be fj=100 Hz. Using a swept sine wave fi . . . I, spatial wavelengths above and below this value may be probed. The spatial wavelength may be reduced by increasing the frequency until the large nonlinear response disappears. In this manner the distance to the over-pressured region can be determined.
Noise from impulsive elastic waves generated from the action of drilling bit 14 on the materials in a formation can be used as a source for the classical time reversal measurements in place of acoustic source 12 in accordance with embodiments of the present invention. In this situation, the drilling bit would be stopped when the amplified time-reversed signals generated by transceivers 22 are employed to generate harmonics in front of drilling bit 14, the harmonic signals being correlated with the time-reversed signals from the drilling bit.
The method described in
Having generally described embodiments of the present invention, the following EXAMPLES provides additional details.
The time-reversed signals may be broadcasted successively at different amplitudes to assist in the detection of the nonlinear signals. As discussed above, the size of the region probed by focused waves in the formation depends of the wavelength used for the first reference signal.
The signal strength increases by a factor of 10 when using reciprocal time reversal over that resulting from the use of conventional sources. This is clear example of an apparatus capable of transmitting elastic wave energy to a formation in a simulated borehole/casing/rock system using the method in accordance with embodiments of the present invention.
Once these contacts are located, drilling can be redirected using apparatus 25 in
As discussed above, with the aid of time reversal, elastic wave energy is focused at a point in space and an impulsive waveform will be generated. Since this process involves waves traveling through materials, and material properties may be strain dependent, the arrival time of the impulsive waveform may be dependent on the amplitude of the excitation. The term of hysteretic nonlinearity a in the equation of state (Equ. 3) governs this effect.
To verify α can be quantified by monitoring the propagation speed of an elastic wave as a function of the strain amplitude, laboratory experiments were performed. Although the propagation of impulsive elastic waves remains the principal measurement, time reversal is not required to generate the strain since the measurements are restricted to a one-dimensional waveguide over a known propagation distance. The hysteretic nonlinearity parameter has never been measured in this manner, so the determination is validated using nonlinear resonant ultrasound spectroscopy.
Returning to
The data shown in
The relative time delay between the signals is also equal to the relative change in speed of the longitudinal wave, Δci/0/c0. Further, at the perturbation level, the relative change in the Young's modulus E (the modulus involved in the propagation of a longitudinal wave in a long thin bar) is related to the relative change in the speed of the longitudinal wave as,
ΔEi/0/E0=2Δci/0/c0 (7)
The relative changes in the elastic modulus over the propagation path of the waveform can be followed as a function of the maximum strain amplitude at the measurement point. The strain component of interest is εxx, where x is axial direction. The strain component εxx can be expressed analytically as a function of the axial component of the particle velocity vx as,
Recall that the particle velocity is obtained from the vibrational motion measured by 3D Scanning Laser Doppler Vibrometer 110.
Reduced data from
Returning to
Any resonance mode can be selected to quantify hysteretic nonlinearity as long as the mode type is purely longitudinal. The vibrational spectra for this experiment are shown in
As depicted in
The slope of the relative change of the resonance frequency is approximately twice the value of the relative change of the Young's modulus observed in the pulse propagation experiment, which is consistent with the analytical relationship between Young's modulus and resonance frequency of a longitudinal mode at the perturbation level,
ΔE/E0=2Δf/f0 (9)
Therefore, the quantification of hysteretic nonlinearity in the pulse propagation experiment and with nonlinear resonant ultrasound spectroscopy are equivalent.
In the pulse propagation experiments, the Young's modulus is approximately constant below 4 microstrains in the conditioning phase and varies linearly with strain above this value, with a sharp transition between the two regimes (see
In summary, application of a method that combines time reversal and elastic nonlinearity (TR NEWS) provides the means to quantitatively probe for over pressured regions in advance of the drilling bit, and to determine the distance to an over pressured region. Moreover, gas/water contacts may be located in accordance with the teachings of the present invention, and drilling directed to more successfully locate hydrocarbons.
The foregoing description of the invention has been presented for purposes of illustration and description and is not intended to be exhaustive or to limit the invention to the precise form disclosed, and obviously many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and its practical application to thereby enable others skilled in the art to best utilize the invention in various embodiments and with various modifications as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the claims appended hereto.
The present application claims the benefit of U.S. Provisional Patent Application No. 62/306,037 for “Time-Reversed Nonlinear Acoustics For Downhole Pressure Measurements” by Paul A. Johnson et al., which was filed on 9 Mar. 2016, and of U.S. Provisional Patent Application No. 62/367,337 for “Time-Reversed Nonlinear Acoustics For Downhole Pressure Measurements” by Paul A. Johnson et al., the entire contents of which patent applications are hereby specifically incorporated by reference herein for all that they disclose and teach.
This invention was made with government support under Contract No. DE-AC52-06NA25396 awarded by the U.S. Department of Energy. The government has certain rights in the invention.
Filing Document | Filing Date | Country | Kind |
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PCT/US2017/021606 | 3/9/2017 | WO | 00 |
Number | Date | Country | |
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62306037 | Mar 2016 | US | |
62367337 | Jul 2016 | US |