The present invention relates generally to drilling and surveying subterranean boreholes such as for use in oil and natural gas exploration. In particular, this invention relates to methods for determining a distance between a twin well and a magnetized target well.
The use of magnetic field measurements in prior art subterranean surveying techniques for determining the direction of the earth's magnetic field at a particular point is well known. Techniques are also well known for using magnetic field measurements to locate subterranean magnetic structures, such as a nearby cased borehole. These techniques are often used, for example, in well twinning applications in which one well (the twin well) is drilled in close proximity and often substantially parallel to another well (commonly referred to as a target well).
The magnetic techniques used to sense a target well may generally be divided into two main groups; (i) active ranging and (ii) passive ranging. In active ranging, the local subterranean environment is provided with an external magnetic field, for example, via a strong electromagnetic source in the target well. The properties of the external field are assumed to vary in a known manner with distance and direction from the source and thus in some applications may be used to determine the location of the target well. In contrast to active ranging, passive ranging techniques utilize a preexisting magnetic field emanating from magnetized components within the target borehole. In particular, conventional passive ranging techniques generally take advantage of magnetization present in the target well casing string. Such magnetization is typically residual in the casing string because of magnetic particle inspection techniques that are commonly utilized to inspect the threaded ends of individual casing tubulars.
In co-pending, commonly assigned, U.S. patent application Ser. No. 11/301,762 to McElhinney, a technique is disclosed in which a predetermined magnetic pattern is deliberately imparted to a plurality of casing tubulars. These tubulars, thus magnetized, are coupled together and lowered into a target well to form a magnetized section of casing string typically including a plurality of longitudinally spaced pairs of opposing magnetic poles. Passive ranging measurements of the magnetic field may then be advantageously utilized to survey and guide drilling of a twin well relative to the target well. For example, the distance between the twin and target wells may be determined from magnetic field strength measurements made in the twin well. This well twinning technique may be used, for example, in steam assisted gravity drainage (SAGD) applications in which horizontal twin wells are drilled to recover heavy oil from tar sands.
While the above described method of magnetizing wellbore tubulars has been successfully utilized in well twinning applications, there is room for yet further improvement. For example, it has been found that the above described longitudinal magnetization method can result in a somewhat non-uniform magnetic flux density along the length of a casing string at distances of less than about 6-8 meters. If unaccounted, the non-uniform flux density can result in distance errors on the order of about ±1 meter when the distance between the two wells is about 5-6 meters. While such distance errors are typically within specification for most well twinning operations, it would be desirable to improve the accuracy of distance calculations between the target and twin wells.
Moreover, passive ranging surveys are typically acquired at about 10 meter intervals along the length of the twin well. More closely spaced distance measurements may sometimes be advantageous (or even required) to accurately place the twin well. For example, more frequent distance measurements would be advantageous during an approach (also referred to in the art as a landing) or during a period of unusual drift in either the target or twin well. Taking more frequent magnetic surveys is undesirable since each magnetic survey requires a stoppage in drilling (and is therefore costly in time).
Therefore, there exists a need for improved methods for determining the distance between a twin well and a magnetically patterned target well. In particular, there is a need for a method that accounts for fluctuations in magnetic field strength and thereby improves the accuracy of the determined distances. There is also a need for a dynamic distance measurement method (i.e., a method for determining the distance between that does not require a stoppage in drilling).
Exemplary aspects of the present invention are intended to address the above described need for improved methods for determining the distance between a twin well and a magnetized target well. In one exemplary embodiment, the invention includes processing the strength of the interference magnetic field and a variation in the field strength along the longitudinal axis of the target well to determine the distance to the target well. In another exemplary embodiment of the invention, measurement of the component of the magnetic field vector aligned with the tool axis may be acquired while drilling and utilized to determine the distance between the two wells in substantially real time. Still other exemplary embodiments of the invention enable both the distance between the twin and target wells and the axial position of the magnetic sensors relative to the target well to be determined. In one of these exemplary embodiments the magnitude and direction of the interference magnetic field vector are processed to determine the distance and the axial position. In another of these exemplary embodiments, the change in direction of the interference magnetic field vector between first and second longitudinally spaced magnetic field measurements may be processed to determine the distance and axial position.
Exemplary embodiments of the present invention provide several advantages over prior art well twinning and distance determination methods. For example, exemplary embodiments of this invention improve the accuracy of distance calculations between twin and target wells. Such improvements in accuracy enable a drilling operator to position a twin well with increased accuracy relative to the target well. Moreover, exemplary embodiments of the invention also enable the distance between the twin and target wells to be determined in substantially real time. These real-time distances may be used, for example, to make real-time steering decisions. Moreover, exemplary embodiments of this invention also enable the axial position of the magnetic sensors relative to the target well to be determined.
In one aspect, the present invention includes a method for determining the distance between a twin well and a target well, the target well being magnetized such that it includes a substantially periodic pattern of opposing north-north (NN) magnetic poles and opposing south-south (SS) magnetic poles spaced apart along a longitudinal axis thereof. The method includes deploying a drill string in the twin well, the drill string including a magnetic sensor in sensory range of magnetic flux emanating from the target well and measuring a magnetic field with the magnetic sensor. The method further includes processing the measured magnetic field to determine a magnitude of an interference magnetic field attributable to the target well and processing the magnitude of the interference magnetic field to determine a first distance to the target well. The method also includes estimating an axial position of the magnetic sensor relative to at least one of the opposing magnetic poles imparted to the target well and processing the first distance in combination with the estimated axial position to determine a second distance to the target well.
In another aspect, this invention includes a method for estimating the distance between a twin well and a magnetized target well in substantially real time during drilling of the twin well. The target well is magnetized such that it includes a substantially periodic pattern of opposing north-north (NN) magnetic poles and opposing south-south (SS) magnetic poles spaced apart along a longitudinal axis thereof. The method includes deploying a drill string in the twin well, the drill string including a magnetic sensor in sensory range of magnetic flux emanating from the target well and measuring an axial component of the magnetic flux in substantially real time during drilling, the axial component substantially parallel with a longitudinal axis of the twin well. The method further includes processing the measured axial component to estimate a magnitude of an interference magnetic field vector attributable to the target well and processing the estimated magnitude of the interference magnetic field vector to estimate the distance between the twin and target wells.
In still another aspect, this invention includes a method for determining a distance between a twin well and a target well, the target well being magnetized such that it includes a substantially periodic pattern of opposing north-north (NN) magnetic poles and opposing south-south (SS) magnetic poles spaced apart along a longitudinal axis thereof. The method includes deploying a drill string in the twin well, the drill string including a magnetic sensor in sensory range of magnetic flux emanating from the target well and measuring a magnetic field with the magnetic sensor. The method further includes processing the measured magnetic field to determine first and second components of an interference magnetic field vector attributable to the target well, the first and second components being selected from the group consisting of (i) a magnitude of the interference magnetic field vector and an angle of the interference magnetic field vector with respect to a fixed reference and (ii) magnitudes of first and second orthogonal components of the interference magnetic field vector. The method also includes processing the first and second components of the interference magnetic field vector in combination with a model relating the first and second components to (i) the distance and (ii) an axial position of the magnetic field sensor relative to the target well to determine the distance between the magnetic field sensor and the target well.
In yet another aspect this invention includes a method for determining a distance between a twin well and a target well, the target well being magnetized such that it includes a substantially periodic pattern of opposing north-north (NN) magnetic poles and opposing south-south (SS) magnetic poles spaced apart along a longitudinal axis thereof. The method includes deploying a drill string in the twin well, the drill string including a magnetic sensor in sensory range of magnetic flux emanating from the target well and measuring a magnetic field at first and second longitudinally spaced locations in the borehole. The method further includes processing the first and second magnetic field measurements to determine first and second directions of an interference magnetic field vector at the corresponding first and second locations and processing the first and second directions and a difference in measured depth between the first and second locations with a model relating a direction of the interference magnetic field vector to the distance between the twin well and the target well to determine the distance.
The foregoing has outlined rather broadly the features and technical advantages of the present invention in order that the detailed description of the invention that follows may be better understood. Additional features and advantages of the invention will be described hereinafter which form the subject of the claims of the invention. It should be appreciated by those skilled in the art that the conception and the specific embodiments disclosed may be readily utilized as a basis for modifying or designing other structures for carrying out the same purposes of the present invention. It should also be realize by those skilled in the art that such equivalent constructions do not depart from the spirit and scope of the invention as set forth in the appended claims.
For a more complete understanding of the present invention, and the advantages thereof, reference is now made to the following descriptions taken in conjunction with the accompanying drawings, in which:
With reference now to
It will be appreciated that the present invention is not limited to the exemplary embodiments shown on
With continued reference to
The magnetic field about the magnetized casing string may be measured and represented, for example, as a vector whose orientation depends on the location of the measurement point within the magnetic field. In order to determine the magnetic field vector due to the target well (e.g., target well 30) at any point downhole, the magnetic field of the earth is typically subtracted from the measured magnetic field vector, although the invention is not limited in this regard. The magnetic field of the earth (including both magnitude and direction components) is typically known, for example, from previous geological survey data or a geomagnetic model. However, for some applications it may be advantageous to measure the magnetic field in real time on site at a location substantially free from magnetic interference, e.g., at the surface of the well or in a previously drilled well. Measurement of the magnetic field in real time is generally advantageous in that it accounts for time dependent variations in the earth's magnetic field, e.g., as caused by solar winds. However, at certain sites, such as an offshore drilling rig, measurement of the earth's magnetic field in real time may not be practical. In such instances, it may be preferable to utilize previous geological survey data in combination with suitable interpolation and/or mathematical modeling (i.e., computer modeling) routines.
The earth's magnetic field at the tool and in the coordinate system of the tool may be expressed, for example, as follows:
M
EX
=H
E(cos D sin Az cos R+cos D cos Az cos Inc sin R−sin D sin Inc sin R)
M
EY
=H
E(cos D cos Az cos Inc cos R+sin D sin Inc cos R−cos D sin Az sin R)
M
EZ
=H
E(sin D cos Inc−cos D cos Az sin Inc) Equation 1
where MEX, MEY, and MEZ represent the x, y, and z components, respectively, of the earth's magnetic field as measured at the downhole tool, where the z component is aligned with the borehole axis, HE is known (or measured as described above) and represents the magnitude of the earth's magnetic field, and D, which is also known (or measured), represents the local magnetic dip. Inc, Az, and R represent the Inclination, Azimuth (relative to magnetic north) and Rotation (also known as the gravity tool face), respectively, of the tool, which may be obtained, for example, from conventional surveying techniques. However, as described above, magnetic azimuth determination can be unreliable in the presence of magnetic interference. In such applications, where the measured borehole and the target borehole are essentially parallel (i.e., within five or ten degrees of being parallel), Az values from the target well, as determined, for example in a historical survey, may be utilized.
The magnetic field vectors due to the target well (also referred to as interference vectors in the art) may then be represented as follows:
M
TX
=M
X
−M
EX
M
TY
=M
Y
−M
EY
M
TZ
=M
Z
−M
EZ Equation 2
where MTX, MTY, and MTZ represent the x, y, and z components, respectively, of the interference magnetic field vector due to the target well and MX, MY, and MZ, as described above, represent the measured magnetic field vectors in the x, y, and z directions, respectively.
The artisan of ordinary skill will readily recognize that in determining magnetic field vectors about the target well it may also be necessary to subtract other magnetic field components from the measured magnetic field vectors. For example, such other magnetic field components may be the result of drill string, steering tool, and/or drilling motor interference. Techniques for accounting for such interference are well known in the art. Moreover, magnetic interference may emanate from other nearby cased boreholes. In SAGD applications in which multiple sets of twin wells are drilled in close proximity, it may be advantageous to incorporate the magnetic fields of the various nearby wells into a mathematical model.
The magnetic field strength due to the target well may be represented, for example, as follows:
M=√{square root over (MTX2+MTY2+MTZ2)} Equation 3
where M represents the magnetic field strength due to the target well (also referred to herein as the interference magnetic field strength) and MTX, MTY, and MTZ are defined above with respect to Equation 2. The magnetic field strength, M, is sometimes also referred to equivalently in the art as the total magnetic field (TMF) and/or the magnetic flux density. As disclosed in the '762 Patent Application, the measured magnetic field strength, M, may be utilized to determine the distance between twin and target wells. For example, the magnetic field strength, M, was disclosed to decrease with increasing distance.
With reference now to
The above-described variation in the calculated distance is due to an approximately periodic variation in the magnetic field strength along the axis of the target well. It has been observed that the magnetic field strength is greater at locations adjacent pairs of opposing magnetic poles than at locations between the pairs of opposing poles (resulting in smaller calculated distances adjacent the pairs of opposing poles than between adjacent pairs). As described above, the calculated distances shown on
d
1
=a ln(M)+b Equation 4
where d1 represents the distance between the two wells, M represents the magnetic field strength (e.g., as determined in Equation 3), and a and b represent empirical fitting parameters.
With reference to
A=sd
1
4
+td
1
3
+ud
1
2
+vd
1
+w Equation 5
where A represents the amplitude of the variation of the magnetic field along the longitudinal axis, d1 represents the distance between the measurement point and the target well, and s, t, u, v, and w represent empirically derived fitting parameters.
In one exemplary embodiment of the present invention, the distance between twin and target wells may be calculated with improved accuracy if the axial position of the sensors 28 (
In accordance with one exemplary embodiment of the present invention, the distance between twin and target wells may be determined as follows:
In step 5, the variation of the magnetic field strength along the axis is assumed to be sinusoidal. It will be appreciated that the invention is not limited to any particular periodic function. Other suitable periodic functions (e.g., a triangular wave function) may also be utilized.
Substantially real-time measurements of the axial component of the magnetic field MZ (or of the interference magnetic field vector, MTZ) may also be utilized to provide a substantially real-time estimate of the distance between the twin and target wells during drilling (i.e., stoppage not required). For example, the interference magnetic field strength, M, may be estimated graphically as shown on
The interference magnetic field strength, M, may also be estimated mathematically from the axial component of the interference magnetic field vector, MTZ, and the axial position of the magnetic sensor, for example, as follows:
where θ represents the axial position of the sensors with respect to the target well, with θ=0 degrees representing a NN opposing pole and θ=180 degrees representing a SS opposing pole. In Equation 6, the periodic variation of MTZ along the axis of the target well is assumed to be approximately sinusoidal. It will be appreciated that the invention is not limited in this regard and that other periodic functions may be utilized. The distance to the target well may then be estimated, for example, by substituting M (estimated via
With reference now to
It will thus be understood that the invention is not limited to embodiments in which the earth's magnetic field is removed from the measured magnetic field (e.g., as described above in Equations 1 and 2). For example, the earth's magnetic field has not been removed from
In the previously described exemplary embodiments of this invention, the measured magnetic field strength of the interference magnetic field vector and the axial position of the magnetic field sensors (in the twin well) relative to the target well are utilized to determine the distance between the twin and target wells. In an alternative embodiment of this invention, the magnetic field vector may be utilized to uniquely determine both the distance between the two wells and the axial position of the magnetic field sensor relative to the opposing magnetic poles imparted to the target well (referred to as a normalized axial position).
The artisan of ordinary skill in the art will readily recognize that any vector may be analogously defined by either (i) the magnitudes of first and second in-plane, orthogonal components of the vector or by (ii) a magnitude and a direction (angle) relative to some in-plane reference. Likewise, the interference magnetic field vector may be defined by either (i) the magnitudes of first and second in-plane, orthogonal components or by (ii) a magnitude and a direction (angle). In the exemplary embodiments shown below, the first and second in-plane, orthogonal components of the interference magnetic field vector are referred to as parallel and perpendicular components (being correspondingly parallel with and perpendicular to the target well). The perpendicular component is defined as being positive when it points away from the target well while the parallel component is defined as being positive when it points in the direction of increasing measured depth. Equivalently, when the magnitude and direction of the interference magnetic field are utilized, an angle of 0 degrees corresponds with the perpendicular component and therefore indicates a direction pointing orthogonally outward from the target. An angle of 90 degrees corresponds with the parallel component and therefore indicates a direction pointing parallel to the target well in the direction of increasing measured depth. The invention is, of course, not limited by such arbitrary conventions.
As described above (as well as in commonly assigned, co-pending U.S. patent application Ser. No. 11/301,762), the pattern of opposing magnetic poles imparted to the target casing string results in a measurable magnetic flux about the casing string. Moreover, as stated above, the interference magnetic field vector is uniquely related to the distance between the twin and target wells and the axial position of the magnetic field sensors relative to the opposing poles imparted to the target well. This may be expressed mathematically, for example, as follows:
M
N
=f
1(d,l)
M
P
=f
2(d,l) Equation 7
where MN and MP define the interference magnetic field vector and represent the magnitude of the components perpendicular (normal) to and parallel with the target well, d represents the distance between the two wells, l represents the normalized axial position of the magnetic field sensors along the axis of the target well, and f1(·) and f2(·) represent first and second mathematical functions (or empirical correlations) that define MN and MP with respect to d and l. In one exemplary embodiment in which the twin and target wells are substantially parallel, the magnitudes MN and MP may be determined from the x, y, and z components of the interference magnetic field vector, for example, as follows:
M
N
=√{square root over (MTX2+MTY2)}
MP=|MTZ| Equation 8
where MTX, MTY, and MTZ are as defined above, for example, with respect to Equation 2. The signs (positive or negative) of MN and MP may be determined as discussed hereinabove from the direction of the interference magnetic field relative to the target well. In the more general case (where the twin and target wells are not parallel), the artisan of ordinary skill would readily be able to derive similar relationships.
The mathematical functions/correlations f1(·) and f2(·) (in Equation 7) may be determined using substantially any suitable techniques. For example, in one exemplary embodiment of this invention, bi-axial magnetic field measurements are made at a two-dimensional matrix (grid) of known orthogonal distances d and normalized axial positions l relative to a string of magnetized tubulars deployed at a surface location. MN and MP may then be determined from the bi-axial measurements (e.g., the first axis may be perpendicular to the target thereby indicating MN and the second axis may be parallel with the target thereby indicating MP). It will be understood that MN and MP may also be determined from tri-axial magnetic field measurements, e.g., via Equation 8. Known interpolation and extrapolation techniques can then be used to determine MN and MP at substantially any location relative to the target well (thereby empirically defining f1(·) and f2(·)). In another exemplary embodiment of this invention, f1(·) and f2(·) may be determined via a mathematical model (e.g., a finite element model) of a semi-infinite string of magnetized wellbore tubulars. Such a model may include, for example, pairs of opposing magnetic poles of known strength and spacing along the string.
One such dipole mathematical model is shown on
Upon measuring MN and MP (the orthogonal and parallel components of the interference magnetic field vector), d and l may be determined using substantially any suitable techniques. For example, d and l may be determined graphically from
d=f
3(MN,MP)
l=f
4(MN,MP) Equation 9
where d, l, MN, and MP are as defined above and f3(·) and f4(·) represent mathematical functions that define d and l with respect to MN and MP. It will be appreciated that substantially any known mathematical inversion techniques, including known analytical and numerical techniques, may be utilized. Equation 9 is typically (although not necessarily) solved for d and l using known numerical techniques, e.g., sequential one-dimensional solvers. The invention is not limited in these regards.
It will be appreciated that the interference magnetic field vector (as represented by MN and MP in
As stated above, the interference magnetic field vector may be equivalently defined by the magnitude and direction (e.g., the angle with respect to the target well) of the vector. Thus, Equation 7 may be rewritten, for example, as follows:
M=f′
1(d,l)
φ=f′2(d,l) Equation 10
where M and φ define the interference magnetic field vector and represent the magnitude (interference magnetic field strength) and direction (the angle relative to the target well) of the vector, d represents the distance between the two wells, l represents the normalized axial position of the magnetic field sensors along the axis of the target well, and f′1(·) and f′2(·) represent alternative mathematical functions (or empirical correlations) that define the magnitude M and direction φ with respect to d and l. M and φ may be determined from MN and MP, for example, as follows:
M=√{square root over (MN2+MP2)}
With reference now to
With reference again to
To further illustrate, note that at axial positions approximately adjacent to either the NN or SS opposing poles (normalized distances of about 0.0, 0.5., 1.0, etc.), φ changes more rapidly with increasing measured depth than at axial positions between the opposing poles (normalized distances of 0.25, 0.75, etc.). Accordingly, assuming that the twin well is substantially parallel with the target well (parallel with the x-axis on
d=f
11(φ1,φ2,ΔMD)
l=f
12(φ1,φ2,ΔMD) Equation 12
where d represents the distance between the twin and target wells (as described above), l represents the normalized axial position of the magnetic field sensors along the axis of the target well (as also described above), φ1 and φ2 represent the direction of the interference magnetic field (with respect to the target well) at the first and second measurement points, ΔMD represents the difference in measured depth between the two measurement points, and f11(·) and f12(·) indicate that that d and l are mathematical functions of φ1, φ2, and ΔMD.
The first and second magnetic field measurements (from which φ1, φ2, and ΔMD are determined) may be acquired either simultaneously at first and second longitudinally spaced magnetic field sensors (e.g., spaced at a known distance along the drill string) or sequentially during drilling of the twin well. The invention is not limited in this regard. The mathematical function/correlations f11(·) and f12(·) may be determined empirically or theoretically, for example, in substantially the same manner as described above with respect to Equation 7 for determining f1(·) and f2(·). Equation 12 may then be solved via substantially any known means (e.g., graphically or numerically as also described above) to determined the distance d to that target well. One exemplary embodiment of a graphical solution is as follows: (i) a horizontal (parallel with the x-axis) segment of length ΔMD is located on
It will be appreciated that the method described above with respect to Equation 12 is not limited to the use of two axially spaced magnetic field measurements. Rather, substantially any number of measurements may be utilized. For example, a method utilizing three or more measurements having known spacing may be advantageously utilized to reduce measurement noise and thereby increase the accuracy of the distance determination. Alternatively, methods utilizing a set of three or more magnetic field measurements may be advantageously used to relax the assumptions made in deriving Equation 12 and therefore to determine other parameters of interest (e.g., an approach angle of the twin well relative to the target well). As stated above, the method described above with respect to Equation 12 inherently assumes that the twin and target wells are substantially parallel when only two magnetic field measurements are utilized. This is typically a good assumption in well twinning operations (such as SAGD operations), since the intent of the twinning operation is to drill substantially parallel wells at some fixed distance from one another. The invention, however, is not limited in this regard as scenarios arise in which the twin well may be approaching or diverging from the target well (i.e., the twin is no longer parallel with the target). In such scenarios it would generally be advantageous to determine the angle of approach (or divergence) between the two wells using three or more axially spaced magnetic field measurements.
With reference again to Equation 12, it will also be appreciated that the distance d and the axial position l may be determined independent of the interference magnetic field strength M. Accordingly, after determining d and l (as described above) the measured interference magnetic field strength may then be utilized, for example, to determine the strength of the magnetic poles imparted to the magnetized target well. The pole strengths may be determined, for example, via substituting d and l (determined via Equation 12) into Equation 10. The interference magnetic field strength M then be used to evaluate (calibrate) the model defined by f′1(·), which typically includes two principle variables; (i) the spacing between opposing magnetic poles and (ii) the strength of the poles (which are assumed to be equal).
Although the present invention and its advantages have been described in detail, it should be understood that various changes, substitutions and alternations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims.
This application claims the benefit of U.S. Provisional Application Ser. No. 60/881,895 entitled Distance Determination From A Magnetically Patterned Target Well, filed Jan. 23, 2007.
Number | Date | Country | |
---|---|---|---|
60881895 | Jan 2007 | US |