The invention generally relates to an apparatus and method for acoustically investigating a tube casing.
One example of a tube casing is a wall of a borehole penetrating an earth formation. Such a wall may comprise an annular space filed with set cement. After the cement has set in the annular space of the casing it is common practice to use acoustic non-destructive testing methods to evaluate its integrity. This evaluation is of prime importance since the cement must guarantee zonal isolation between different formations in order to avoid flow of fluids from the formations (water, gas, oil) through the annular space of the casing.
A common cause for loss of isolation from the casing is the presence of a channel in the casing, i.e., an angular section of the annulus that is filled by a liquid instead of cement. Another cause for loss of isolation may be the presence of a microscopic annular space (microannulus) between Ie tube and the cement. In both cases a risk occurs that fluids flow along the cement casing and generate problems of fluid migration, or even worse a collapse of the borehole. It is therefore essential to be able to detect both causes, i.e., channel and microannulus, and remedy to their presence in the casing.
One possible way of remedy when a channel is detected in the casing, is to shoot a hole through the casing and to inject a cement slurry through the hole into the channel to seal the channel. This action is commonly referred to as “squeeze”. A squeeze is expensive to perform.
Unfortunately it may in some cases of evaluation happen that a channel is detected although no channel is present in the casing, leading to a useless squeeze and unnecessary expenses. One reason for such a “false-positive” detection may be the presence of a microannulus. Conventional detection and evaluation methods appear to be mislead by the presence of a microannulus and to deliver a value for the percentage of the annulus filled by cement that is lower than reality.
In a first aspect the invention provides a method for determining components of a tube casing surrounding a tube, using amplitude measurements of an acoustic signal wavefront emitted inside the tube. The acoustic signal wavefront is affected by the components of the tube casing while propagating in the tube. An attenuation A(E) of the amplitude inside the tube is determined. A percentage of cement bonded φC in the tube casing, a percentage of cement de-bonded φD in the tube casing and a percentage of liquid φW in the tube casing, are determined by inverting the following equations:
A(E)=φC*A(Efc)+φW*A(Efp)+φD*A(Efd)
logEP1=φC*logEP1,fc+φW*logEP1,fp+φD*logEP1,fd
φC+φW+φD=1
wherein EP1 is the amplitude measured at a location P1, EP1,fp is the amplitude at the location P1 for a free-pipe tube casing, EP1,fc is the amplitude at the location P1 for a fully cemented tube casing, EP1,fd is the amplitude at the location P1 for a fully de-bonded tube casing, and A(Efp), A(Efc), A(Efd) being the attenuations of amplitude in case the tube casing is respectively free-pipe, fully cemented, and fully de-bonded.
In a second aspect the invention provides a method for determining components of a tube casing surrounding a tube, using amplitude measurements of an acoustic signal wavefront emitted inside the tube. The acoustic signal wavefront is affected by the components of the tube casing while propagating in the tube. A coupling Amplitude Eo is determined by extrapolating amplitude measurements made at various locations in the tube to a location of a source of the acoustic signal. A percentage of cement bonded φC in the tube casing, a percentage of cement de-bonded φD in the tube casing and a percentage of liquid φW in the tube casing, are determined by inverting the following equations:
logEP1=φC*logEP1,fc+φW*logEP1,fp+φD*logEP1,fd
logE0=φC*logE0,fc+φW*logE0,fp+φD*logE0,fd
φC+φW+φD=1
wherein EP1 is the amplitude measured at a location P1, EP1,fp is the amplitude at the location P1 for a free-pipe tube casing, EP1,fc is the amplitude at the location P1 for a fully cemented tube casing, EP1,fd is the amplitude at the location P1 for a fully de-bonded tube casing, E0,fp is the coupling amplitude for a free-pipe tube casing, E0,fc is the coupling amplitude for a fully cemented tube casing, E0,fd is the coupling amplitude for a fully de-bonded tube casing.
In a third aspect the invention provides a method for determining components of a tube casing surrounding a tube, using amplitude measurements of an acoustic signal wavefront emitted inside the tube. The acoustic signal wavefront is affected by the components of the tube casing while propagating in the tube. An attenuation A(E) of the amplitude inside the tube, is determined and a coupling Amplitude Eo is found by extrapolating amplitude measurements made at various locations in the tube to a location of a source of the acoustic signal. A percentage of cement bonded φC in the tube casing, a percentage of cement de-bonded φD in the tube casing and a percentage of liquid φW in the tube casing, are dertmined by inverting the following equations:
logE0=φC*logE0,fc+φW*logE0,fp+φD*logE0,fd
A(E)=φC*A(Efc)+φW*A(Efp)+φD*A(Efd)
φC+φW+φO=1
wherein A(Efp), A(Efc), A(Efd) correspond respectively to the attenuations of amplitude in case the tube casing is free-pipe, fully cemented, and fully debonded, and E0,fp is the coupling amplitude for a free pipe tube casing, E0,fd is the coupling amplitude for a fully cemented tube casing, E0,fd is the coupling amplitude for a fully de-bonded tube casing.
Preferably the coupling amplitude Eo determined by defining a linear function E(X)=A*X+Eo in which an amplitude E(X) of an acoustic signal wavefront measured at a location X in the tube is subject to an attenuation A, and calculating E(X)=E(0) for a location where X=0, corresponding to a source of the acoustic signal in the tube.
The invention will now be described in greater detail with reference to the accompanying drawings, in which:
Same references will be used to reference same elements in the Figures throughout the description.
Measurement Set-Up
As an example the ASS 201 may be a ceramic piezo-electrical transducer. The distances separating the ASS 201 from the ASR 202 and 203 may for example be respectively 90 cm and 150 cm. The ASS 201 emits acoustic pulses having a duration of 50 μs with a rate of 10 to 60 pulses per second. A typical main frequency of the acoustic signal may be 20 kHz. Other frequencies may be used in other examples.
Every pulse emitted by the ASS 201 generates a wavefront that propagates through the tube 102. After interacting with the tube 102 and the casing 103, the acoustic wave reaches the ASRs 202 and 203 where the time dependent amplitudes are measured. The measured amplitude is in fact the result of a composite wave that corresponds to an addition of waves that have travelled different paths (tube, casing . . . ). The measured amplitude reflects an acoustic impedance and an acoustic coupling that exists between the tube and a content of the adjacent casing.
It is convenient to measure amplitudes of a determined peak as the determined peak may more easily be identified as it propagates with the wavefront from the ASR 202 to the ASR 203.
Attenuation of Amplitude
An attenuation of the amplitude of the acoustic signal during propagation of the wavefront through the tube in longitudinal direction may be determined by evaluating measurements taken with two separate ASRs.
For example we may consider two ASRs, the first of which is 2.4 ft (0.73152 m) away from the source, the second of which is 3.4 ft (1.03632 m) away from the source, and calculate the attenuation as follows:
wherein:
A is the attenuation factor in dB/ft,
E11 is the amplitude of the E1 peak at the first ASR (2.4 ft),
E12 is the amplitude of the E1 peak at the second ASR (3.4 ft),
L is the distance between the first ASR and the second ASR.
Interpretation of Measured Acoustic Amplitudes
It has previously been stated that the measured amplitude reflects an acoustic impedance and an acoustic coupling that exists between the tube and a content of the adjacent casing. The following discussion will be based on consideration of the peak E1, as an example. It is understood that any other peak or energy computed inside a temporal window taken from the curve of amplitude measurement may be considered instead as appropriate.
There are generally 3 extreme cases that may occur:
Various methods exist in prior art to establish a quantitative evaluation of the components present in the casing.
One example method described in Grosmangin et al., A Sonic Method for Analysing the quality of Cementation of Borehole Casings, J Pet. Tech, Trans., AIME, 222, February 1961, allows to evaluate a percentage of cement in the casing by making use of a parameter called Bond Index (BI) as follows:
wherein:
E1measured is the measured amplitude,
E1fp is the value of the amplitude in the free pipe case, and
E1fc is the value of the amplitude in the fully cemented case.
The BI is mainly adapted to determine a percentage of cement bonded in the tube casing (φC) and a percentage of liquid in the tube casing (φW). An example of such a situation is shown in
The BI may however be subject to false interpretation when in presence of a microannulus. A percentage of the microannulus in the casing is referenced as φD.
Another example method described in Leslie H. D., Selliers J. de, Pittman D. J., Coupling and Attenuation: A New Measurement Pair in Cement Bond Logging, SPE 16207, 1984, makes use of a Coupling Amplitude (CA) to take into account the effect of a microannulus on the measured amplitude. In this example, the amplitude equals a value of the amplitude for an effective spacing equal to zero, wherein the effective spacing is the source-receiver distance where the curve of fully bonded cement intersects the curve of fully debonded cement in the plot peak amplitude/source-receiver spacing. Also, a Cement Index (CI) is defined in addition to the Bond Index. The CI allows to determine the percentage of cement φC in the casing even if the cement is separated from the tube by a microannulus.
In the further description of embodiments of the present invention, the Coupling Amplitude is defined as being a value E0 of the amplitude at a location of the tube corresponding to the source of the acoustic signal. The value E0 of the Coupling Amplitude may be obtained by considering a linear function representing a value of the amplitude as a function of a distance to the source of acoustic signal. The value of the linear function at a zero distance is the value E0 of the Coupling Amplitude.
Considering for example two measurements E1X1 and E1X2 of the amplitude of the peak E1 made at locations X1 and X2, we have following equations defining a linear function E(X), wherein A represents the attenuation of the amplitude:
E(X1)=E1X1=A*X1C+E0 (1)
E(X2)=E1X2=A*X2C+E0 (2)
wherein X1C and X2C are corrected values of X1 and X2 corresponding to the distance between receiver and source minus a path that is the sum of an acoustic path between source and casing and an acoustic path between casing and receiver, according to Snell's law and as illustrated in
X1C=X1−2*h*tan(α)
X2C=X2−2*h*tan(α).
The parameter h corresponds to an orthogonal distance between the Cement Bond Evaluating Device and the casing, also known as the standoff of the tool. The angle α may be obtained as follows:
α=a sin(vfluid/vcasing)
wherein vfluid and vcasing are known acoustic velocities of fluid surrounding the Cement Bond Evaluating Device and of the casing.
E0 is thus obtained by resolving equations (1) and (2) as follows:
According to measurement results obtained in the frame of the present invention it was found that the respective percentages φC, φW and φD may be related in the following 4 equations (3), (4), (5) and (6), involving measured and calculated values of the attenuation A(E) of an acoustic signal and the coupling amplitude E0 for this signal:
A(E)=φC*A(Efc)+φW*A(Efp)+φD*A(Efd) (3)
logEP1=φC*logEP1,fc+φW*logEP1,fp+φD*logEP1,fd (4)
logE0=φC*logE0,fc+φW*logE0,fp+φD*logE0,fd (5)
φC+φW+φD=1 (6)
In equation (3), A(Efc), A(Efp) and A(Efd) are attenuations of the amplitude in extreme cases corresponding respectively to the fully cemented, the free-pipe and the fully de-bonded cases.
In equation (4), EP1 is the amplitude of the acoustic signal measured at a location P1. EP1,fc′, EP1,fp and EP1,fd are amplitudes of the acoustic signal at the location P1 in extreme cases corresponding respectively to the fully cemented, the free-pipe and the fully de-bonded cases.
In equation (5), E0,fc, E0,fp and E0,fd are coupling amplitudes in extreme cases corresponding respectively to the fully cemented, the free-pipe and the fully de-bonded cases.
Equation (6) reflects that the sum of all percentages should be 100%.
Hence it is possible to obtain the percentages φC, φW and φD by inverting any combination of 3 equations from the 4 equations. For example the percentages may be obtained by inverting the following systems of equations:
(3), (5) and (6);
(4), (5) and (6);
(3), (4) and (6).
Hence it is possible, using the invention, to obtain the three percentages of cement, liquid and microannulus, based on values of the coupling amplitude and/or of the attenuation in the extreme situations of the fully cemented, free-pipe, and fully de-bonded cases.
In box 500 the attenuations for the extreme cases of free-pipe, fully cemented and fully de-bonded are determined. These attenuations have to be determined once only for a given set of borehole conditions defined by pressure and temperature and may be re-used each time when a new determining of components of the tube is made with the given set of borehole conditions, since these attenuations have constant values. These attenuations may for example be determined by means of measurements performed on a prepared tube outside of the borehole.
In box 501 coupling amplitudes for the extreme cases of free-pipe, fully cemented and fully de-bonded are determined. These coupling amplitudes have to be determined once only and may be re-used each time a new determining of components of the tube is made, since these coupling amplitudes have constant values. These coupling amplitudes may for example be determined by means of measurements performed on a prepared tube outside of the borehole.
In box 502 acoustic measurements are performed to determine components of the tube casing inside the borehole. These measurements are used to compute the attenuation A(E) in box 503 and the coupling amplitude Eo in box 504.
At this point we have obtained the parameters for equations (3), (5) and (6). The equations are inverted in box 505 using well-known solving algorithms and as a result values for the percentages φC, φW, φD are obtained.
Having described preferred embodiments of the invention with reference to the accompanying drawings, it is to be understood that the invention is not limited to these precise embodiments and that various changes and modifications could be effected therein by a person skilled in the art without departing from the spirit or scope of the invention as defined in the appended claims. In particular the invention is not limited to be used to evaluate components of a cemented tube casing, and may for example well apply to other materials used in casings such as resin or any other material that could replace cement.
Notations Used Throughout the Description
Number | Date | Country | Kind |
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03290833.7 | Apr 2003 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP04/04918 | 3/22/2004 | WO | 7/28/2006 |