1. Field
Certain embodiments described herein relate generally to systems and methods for using sensor measurements and at least one geometric constraint to determine at least one location of at least one wellbore casing within a wellbore conductor.
2. Description of the Related Art
Within a wellbore conductor, multiple wellbore casings may be inserted (e.g., by running multiple casings within the conductor and cementing the casings in place). Rotary steerable drilling tools can be equipped with survey instrumentation, such as measurement while drilling (MWD) instrumentation, which provides information regarding the orientation of the survey tool, and, hence, the orientation of the well at the tool location. Survey instrumentation can also be lowered into casings via survey strings before drilling takes place. Survey instrumentation can make use of various measured quantities such as one or more of acceleration, magnetic field, and angular rate to determine the orientation of the tool and the associated wellbore or wellbore casing with respect to a reference vector such as the Earth's gravitational field, magnetic field, or rotation vector. The determination of such directional information at generally regular intervals along the path of the well can be combined with measurements of well depth to allow the trajectory of the well to be estimated.
In certain embodiments, a method of determining at least one location of at least one wellbore casing within a wellbore conductor is provided. In certain embodiments, the method comprises providing sensor measurements generated by at least one sensor within the wellbore conductor. The sensor measurements of certain embodiments are indicative of at least one location of the at least one wellbore casing within the wellbore conductor as a function of position along the wellbore conductor. The method of certain embodiments further comprises calculating the at least one location of the at least one wellbore casing using the sensor measurements and at least one geometric constraint. The at least one geometric constraint of certain embodiments originates at least in part from at least one physical parameter of the wellbore conductor, or at least one physical parameter of the at least one wellbore casing, or both.
In certain embodiments, a system is provided for determining at least one location of at least one wellbore casing within a wellbore conductor. In certain embodiments, the system comprises a data memory that stores sensor measurements corresponding to measurements from at least one sensor within the wellbore conductor. The sensor measurements of certain embodiments are indicative of at least one location of the at least one wellbore casing within the wellbore conductor as a function of position along the wellbore conductor. The system of certain embodiments further comprises a computer system in communication with the data memory. The computer system of certain embodiments is operative to calculate the at least one location of the at least one wellbore casing using the sensor measurements and at least one geometric constraint. The at least one geometric constraint of certain embodiments originates at least in part from at least one physical parameter of the wellbore conductor, or at least one physical parameter of the at least one wellbore casing, or both.
In certain embodiments, a system is provided for determining at least one location of at least one wellbore casing within a wellbore conductor. In certain embodiments, the system comprises a first component that provides sensor measurements corresponding to measurements from at least one sensor within the wellbore conductor. The sensor measurements of certain embodiments are indicative of at least one location of the at least one wellbore casing within the wellbore conductor as a function of position along the wellbore conductor. The system of certain embodiments further comprises a second component that calculates the at least one location of the at least one wellbore casing using the sensor measurements and at least one geometric constraint. The at least one geometric constraint of certain embodiments originates at least in part from at least one physical parameter of the wellbore conductor, or at least one physical parameter of the at least one wellbore casing, or both. The system of certain embodiments further comprises a computer system operative to execute the first and second components.
In certain embodiments, a computer-readable medium is provided for determining at least one location of at least one wellbore casing within a wellbore conductor. The computer-readable medium has computer-executable components that are executed on a computer system having at least one computing device. In certain embodiments, the computer-executable components comprise a first component that provides sensor measurements corresponding to measurements from at least one sensor within the wellbore conductor. The sensor measurements of certain embodiments are indicative of at least one location of the at least one wellbore casing within the wellbore conductor as a function of position along the wellbore conductor. The computer-executable components of certain embodiments further comprise a second component that calculates the at least one location of the at least one wellbore casing using the sensor measurements and at least one geometric constraint. The at least one geometric constraint of certain embodiments originates at least in part from at least one physical parameter of the wellbore conductor, or at least one physical parameter of the at least one wellbore casing, or both.
Certain embodiments described herein provide methods of determining a location of a wellbore casing within a wellbore conductor. Such methods have several applications. For example, in some situations, two or more casings are run through a single conductor. Multiple casings could be used, for example, to make more efficient use of available slots in a template on an off-shore platform. In such a situation, the outer conductor might be nominally vertical, and the two or more casings within it might define initial, near vertical trajectories of two or more wells. In some such situations, beneath the conductor, each well might be required to build inclination with increasing depth so as to move in the direction of a designated target area.
In
However, the magnitude and direction of d(x) are likely to depend on the value of x. Although the magnitude and direction of d(x) might be known at the top of the well (when x=0), their values lower down the conductor 100 are more uncertain. This uncertainty can arise, for example, because the casings 102, 104 can move within the outer conductor 100. In some situations, guides used to control the eventual paths of the casings 102, 104 are inserted into the conductor 100 after the conductor 100 is in place. For example, guides having apertures or gaps designed to allow the casings 102, 104 to fit therethrough can be lowered into the conductor 100 on two pipes that extend down the conductor 100 (e.g., to the bottom of the conductor 100). The guides are installed or attached at intervals along these pipes and the casings 102, 104 are then inserted into the conductor 100 through the gaps in the guides. However, as with the unguided configuration in which guides are not used, the magnitude and direction of d(x) may also be uncertain when guides are used. For example, movement of the pipes and/or the guides (e.g., twisting within the conductor 100) during installation of the guides may result in the gaps being located away from their intended positions. In addition, the casings 102, 104 might also move more freely once they pass the lowestmost guide, thereby introducing uncertainty in the values of the magnitude and direction of d(x). Guides are sometimes avoided because the movement (e.g., twisting) of the whole guide structure during insertion into the conductor 100 can make the subsequent operation of inserting the casings 102, 104 difficult. Additionally, a guide structure is typically only inserted into conductors that are vertical or very close to vertical. When guides are not used, the uncertainty in the values of the magnitude and direction of d(x) is often greater than when guides are used.
As schematically illustrated in
The foregoing example thus illustrates at least one reason it would be useful to accurately determine the location of a wellbore casing within a wellbore conductor. In particular, in the foregoing example it would be useful to accurately determine the positions of the two or more wellbore casings as they emerge from the lower end of the conductor, before further development of each well takes place. While conventional surveying techniques can provide an estimate of the positions of the two or more casings at the lower end of the conductor in this example, there is a substantial possibility that the bottom-hole positions would not be determined with sufficient accuracy. Certain embodiments described herein provide methods of determining a location of a wellbore casing within a wellbore conductor with greater or more acceptable accuracy by making use of one or more geometrical constraints.
Sensor measurements indicative of the at least one location of the at least one wellbore casing can be provided in many ways. For example, in certain embodiments, providing sensor measurements comprises loading or retrieving data from memory or any other computer storage device. In certain such embodiments and in certain other embodiments, providing sensor measurements comprises receiving signals or data directly from at least one sensor within the conductor.
Moreover, there are many ways sensor measurements from the sensors 122, 124 can be indicative of at least one location of the at least one wellbore casing 102, 104 within the wellbore conductor 100 as a function of position along the wellbore conductor 100. In certain embodiments, the first sensor 122 generates measurements with respect to the first casing 102 at positions x0, x1, . . . , xm along the conductor 100 and the second sensor 124 generates measurements with respect to the second casing 104 at positions y0, y1, . . . , yn along the conductor 100. The measurements generated by the first sensor 122 are indicative of at least one location of the first casing 102 at a position {circumflex over (x)} along the conductor 100. Similarly, the measurements generated by the second sensor 124 are indicative of at least one location of the second casing 102 at a position ŷ along the conductor 100. In certain embodiments, the sensor measurements comprise measurements generated at generally regular intervals along the conductor 100. Thus, in
There are also several possibilities for the location or locations of the casings 102, 104 of which the sensor measurements are indicative. For example, in certain embodiments, the sensor measurements from a sensor 122 are taken at intervals of depth or position along the casing 102 or conductor 100. Moreover, in certain embodiments, the sensor measurements from the sensor 122 are indicative of the location of the center of a cross-section of the casing 102. In certain embodiments, the sensor measurements are indicative of the location of a point on an inner perimeter of a cross-section of the casing 102. In certain embodiments, the sensor measurements are indicative of the location or locations of the casings 102, 104 with respect to a designated reference frame. In certain such embodiments, the reference frame is the local geographic frame denoted by the direction of true north, true east and the local vertical. In certain embodiments, the origin of the reference frame is defined by the starting position of the casing 102.
There are several physical parameters of the wellbore conductor 100 and/or the at least one wellbore casing from which the one or more geometric constraints can originate at least in part. For example, in certain embodiments, the conductor 100 is generally cylindrical. In certain such embodiments, the at least one physical parameter of the conductor 100 can be a cross-sectional dimension of the conductor 100. For example, in certain such embodiments, the one or more geometric constraints originate at least in part from the inner diameter or some other diameter of a cross section of the conductor 100 and/or the inner perimeter or some other perimeter of a cross section of the conductor 100 and/or some other geometrical parameter relating to the cross-sectional shape of the conductor 100. Similarly, in certain embodiments, at least one casing 102 is generally cylindrical. In certain such embodiments, the at least one physical parameter of the at least one cylindrical casing 102 can be a cross-sectional dimension of the at least one casing 102. For example, in certain such embodiments, the one or more geometric constraints originate at least in part from the outer diameter or some other diameter of a cross section of the casing 102 and/or the outer perimeter or some other perimeter of a cross section of the casing 102 and/or some other geometrical parameter relating to the cross-sectional shape of the casing 102.
In certain embodiments, the geometric constraint is a minimum or maximum distance between casings. For example,
where D is the inner diameter of the conductor 100 and d is the outer diameter of each of the three casings 102, 104, 106. Similarly, as
In certain embodiments, the conductor 100 is not aligned completely vertically, making it likely that the two or more casings will eventually touch the conductor 100 and/or one another. For example, an alignment 0.1 to 0.2 degrees off of the vertical in a large-diameter conductor 100 that is 300 meters or longer is sufficient to make it likely that two casings 102, 104 within the conductor 100 will touch the “lower side” of the conductor 100 before emerging from the bottom of the conductor 100. As
In a second operational block 1120 of
In certain embodiments, one or more sensors are components of a wireline survey system and are lowered and raised within at least some of the one or more casings to survey the location or locations of the casings. In certain other embodiments, one or more sensors are components of one or more of the casing or casings (e.g., are mounted at fixed positions within a casing) and are installed with those one or more casings within the conductor. In certain other embodiments, one or more sensors are components of the wellbore conductor (e.g., are mounted at fixed positions within the conductor and are configured to provide information regarding the locations of casings within the conductor).
In certain embodiments, a system for determining at least one location of at least one wellbore casing 102 within a wellbore conductor 100 is provided. The system comprises a data memory that stores sensor measurements indicative of at least one location of the at least one wellbore casing 102 within the wellbore conductor 100 as a function of position along the wellbore conductor 100. The data memory can be in any of several forms. For example, in certain embodiments, the data memory comprises read-only memory, dynamic random-access memory, flash memory, hard disk drive, compact disk, and/or digital video disk.
The system further comprises a computer system or controller in communication with the data memory. The computer system is operative to calculate at least one location of the at least one wellbore casing 102 using the sensor measurements and at least one geometric constraint originating at least in part from at least one physical parameter of the wellbore conductor 100, or at least one physical parameter of the at least one wellbore casing 102, or both. In certain embodiments, the computer system comprises a microprocessor operative to perform at least a portion of one or more methods described herein of determining at least one location of at least one wellbore casing 102. The computer system can comprise hardware, software, or a combination of both hardware and software. In certain embodiments, the computer system comprises a standard personal computer or microcontroller. In certain embodiments, the computer system is distributed among multiple computers. In certain embodiments, the computer system comprises appropriate interfaces (e.g., network cards and/or modems) to receive measurement signals from a sensor 122. The computer system can comprise standard communication components (e.g., keyboard, mouse, toggle switches) for receiving user input, and can comprise standard communication components (e.g., image display screen, alphanumeric meters, printers) for displaying and/or recording operation parameters, casing orientation and/or location coordinates, or other information relating to the conductor 100, the at least one casing 102 and/or a survey string 132. In certain embodiments, at least a portion of the computer system is located within a downhole portion of the survey string 132. In certain other embodiments, at least a portion of the computer system is located at the surface and is communicatively coupled to a downhole portion of the survey string 132 within the wellbore casing 102. In certain embodiments, signals from the downhole portion are transmitted by a wire or cable (e.g., electrical or optical) extending along an elongate portion of the survey string 132. In certain such embodiments, the elongate portion may comprise signal conduits through which signals are transmitted from a sensor 122 within the downhole portion to the controller and/or the computer system with which the controller is in communication. In certain embodiments in which the controller is adapted to generate control signals for various components of the downhole portion of the survey string 132, the elongate portion of the survey string 132 is adapted to transmit the control signals from the controller to the downhole portion.
In certain embodiments, a system for determining at least one location of at least one wellbore casing 102 within a wellbore conductor 100 is provided. The system comprises first and second components, wherein the first component provides sensor measurements and the second component calculates at least one location of the at least one wellbore casing 102 using the sensor measurements and at least one geometric constraint. The first and second components each can comprise hardware, software, or a combination of both hardware and software. In certain embodiments, the first component comprises software operative to retrieve sensor measurements stored in a data memory. In certain such embodiments and in certain other embodiments, the first component comprises software and/or hardware operative to relay signals generated by a sensor 122. In certain such embodiments, the first component is operative to relay the signals to the second component and/or a computer system described herein. In certain embodiments, the second component comprises a microprocessor operative to perform at least a portion of one or more methods described herein of determining at least one location of at least one wellbore casing 102. In certain such embodiments and in certain other embodiments, the second component comprises software that, when executed, performs at least a portion of one or more methods described herein of determining at least one location of at least one wellbore casing 102.
The system further comprises a computer system operative to execute the first and second components. In certain embodiments, the computer system comprises a microprocessor operative to execute the first and second components. In certain embodiments, the computer system comprises a bus operative to transfer data between the first and second components. The computer system can comprise hardware or a combination of both hardware and software. In certain embodiments, the computer system comprises a standard personal computer. In certain embodiments, the computer system is distributed among multiple computers. In certain embodiments, the computer system comprises appropriate interfaces (e.g., network cards and/or modems) to receive measurement signals from a sensor 122. The computer system can comprise standard communication components (e.g., keyboard, mouse, toggle switches) for receiving user input, and can comprise standard communication components (e.g., image display screen, alphanumeric meters, printers) for displaying and/or recording operation parameters, casing orientation and/or location coordinates, or other information relating to the conductor 100, the at least one casing 102 and/or a survey string 132.
In certain embodiments, a computer-readable medium for determining at least one location of at least one wellbore casing 102 within a wellbore conductor 100 is provided. The computer-readable medium can be in any of several forms. For example, in certain embodiments, the computer-readable medium comprises read-only memory, dynamic random-access memory, flash memory, hard disk drive, compact disk, and/or digital video disk. The computer-readable medium has computer-executable components, executed on a computer system having at least one computing device. In certain such embodiments, the computer-executable components comprise first and second components as described above with respect to other embodiments, wherein the first component provides sensor measurements and the second component calculates at least one location of the at least one wellbore casing 102 using the sensor measurements and at least one geometric constraint. The computer system on which the computer-executable components are executed can be any of the computer systems described above with respect to other embodiments.
In certain embodiments, multiple surveys of each casing within the conductor are conducted. In certain embodiments, quality control tests are carried out to check for gross errors in these surveys. In some such embodiments, provided that the surveys are free from gross errors, an average trajectory is generated for each casing using the constituent positional surveys that have been conducted. In certain of these embodiments, determining the location of a given casing comprises determining the position of the center of the casing within the cross section of the conductor at a particular position along the conductor. In certain such embodiments, the distance and direction from the center of one casing to the center of another is determined at various positions along the length of the conductor and a statistical trend analysis of these data is performed. Geometrical constraints are imposed by the surrounding conductor, which bounds the casing trajectories. For example, in certain embodiments the trajectories must all lie within the inner diameter D of the conductor.
Two Unguided Casings Within a Conductor
In certain embodiments, two casings 102, 104 of equal diameter are placed within the conductor 100. As illustrated in
In certain embodiments, the location of the center of a casing 102, 104 at a given depth or position x along the conductor 100 is specified in terms of coordinates. As an example, the following description uses north and east coordinates, although other coordinate systems may be used. The center-to-center separation d(x) at position x is given by
d(x)=√{square root over ((N2(x)−N1(x))2+(E2(x)−E1(x))2)}{square root over ((N2(x)−N1(x))2+(E2(x)−E1(x))2)}{square root over ((N2(x)−N1(x))2+(E2(x)−E1(x))2)}{square root over ((N2(x)−N1(x))2+(E2(x)−E1(x))2)}, (Eq. 1)
and, as schematically illustrated in
where N1(x) and E1(x) are the measured north and east coordinates of the first casing 102 at position x along the conductor and N2(x) and E2(x) are the measured north and east coordinates of the second casing 104 at x. Depending on the conventions used for the coordinate system (e.g., the north-east coordinates), angles, and/or the reference direction, other versions of Equation (2) may be used. Similarly, a suitable range for the arctangent function may be chosen depending on the conventions used for the coordinate system, the angles, the reference direction and/or the locations of the casings 102, 104 within the conductor 100.
Three Unguided Casings Within a Conductor
In certain embodiments, three casings 102, 104, 106 of equal outer diameter d are inserted within the conductor 100. In certain such embodiments, it is appropriate to monitor the sum of the pairwise separations between the centers of the three casings 102, 104, 106 as a function of position along the conductor 100. As illustrated in
The minimum total center-to-center separation for three casings 102, 104, 106 is 3d, which occurs when the casings 102, 104, 106 are in contact with one another, as illustrated in
In certain embodiments, the location of the center of a casing 102, 104, 106 at a given depth or position x along the conductor is specified in terms of north and east coordinates. The center-to-center separation between the ith and jth casings at position x is
di,j(x)=√{square root over ((Nj(x)−Ni(x))2+(Ej(x)−Ei(x))2)}{square root over ((Nj(x)−Ni(x))2+(Ej(x)−Ei(x))2)}{square root over ((Nj(x)−Ni(x))2+(Ej(x)−Ei(x))2)}{square root over ((Nj(x)−Ni(x))2+(Ej(x)−Ei(x))2)}, (Eq. 3)
and the total center-to-center separation at position x is
d(x)=d1,2(x)+d2,3(x)+d3,1(x), (Eq. 4)
where Ni(x) and Ei(x) are the measured north and east coordinates of the ith casing at position x along the conductor 100. As schematically illustrated in
As described above with respect to Equation (2), the terms of Equation (5) and/or the range of the arctangent function used therein may depend on the conventions used for the coordinate system, the angles, the reference direction, and/or the locations of the casings 102, 104, 106 in the conductor 100. At any given position x along the conductor 100, the centers of the three casings 102, 104, 106 form a triangle. The internal angles βi(x) of this triangle at the vertex corresponding to the center of the ith casing can be calculated using well known geometric relations. The formula for βi(x) may depend, however, on the conventions used for the coordinate system, the angles, the reference direction, and/or the locations of the casings 102, 104, 106 in the conductor 100. For example, if, as illustrated in
β1(x)=α3.1(x)−α1.2(x)−180°. (Eq. 6)
The value of α3.1(x) may depend in part on the locations of the casings 102, 104, 106 within the conductor 100, so whether Equation (6) applies may depend in part on the locations of the casings 102, 104, 106 within the conductor 100. Similarly, Equation (6) may need to be adjusted if, for example, negative values for angles are allowed. In certain embodiments, the relative positions of the casings 102, 104, 106 are tracked by monitoring the direction of the casing direction vector with respect to a given casing and a reference direction (e.g., north). For example, in some situations, the direction φ1(x) of the casing direction vector 900 with respect to the first casing 102 and reference north at position x is
φ1(x)=α1,2(x)−β2(x)+90°. (Eq. 7)
However, as with Equations (2), (5) and (6), the form of Equation (7) for the formula for φ1(x) may depend on the conventions used for the coordinate system, the angles, the reference direction, and/or the locations of the casings 102, 104, 106 in the conductor 100.
Four Unguided Casings Within a Conductor
In certain embodiments, four casings 102, 104, 106, 108 of equal outer diameter d are inserted within the conductor 100. At a given position along the conductor 100, the centers of the four casings 102, 104, 106, 108 form a quadrilateral 700, as schematically illustrated in
In certain embodiments, the location of the center of a casing 102, 104, 106, 108 at a given depth or position x along the conductor 100 is specified in terms of north and east coordinates. The center-to-center separation between the ith and jth casings at position x is
di,j(x)=√{square root over ((Nj(x)−Ni(x))2+(Ej(x)−Ei(x))2)}{square root over ((Nj(x)−Ni(x))2+(Ej(x)−Ei(x))2)}{square root over ((Nj(x)−Ni(x))2+(Ej(x)−Ei(x))2)}{square root over ((Nj(x)−Ni(x))2+(Ej(x)−Ei(x))2)}, (Eq. 8)
and the total center-to-center separation at position x is
d(x)=d1,2(x)+d2,3(x)+d3,4(x)+d4,1(x), (Eq. 9)
where Ni(x) and Ei(x) are the measured north and east coordinates of the ith casing at position x along the conductor 100 and where the first and third casings 102, 106 are on opposite vertices of the quadrilateral 700 and the second and fourth casings 104, 108 are on opposite vertices of the quadrilateral 700. As schematically illustrated in
As described above with respect to Equations (2) and (5), the terms of Equations (10) and (11) and/or the range of the arctangent function used therein may depend on the conventions used for the coordinate system, the angles, the reference direction, and/or the locations of the casings 102, 104, 106 in the conductor 100.
Application of Example Algorithm
As indicated above, in certain embodiments, there are at least two unguided wellbore casings within a wellbore conductor. In certain such embodiments, the following algorithm or one of the variants thereof described herein is used to determine at least one location of each of the two unguided wellbore casings within a wellbore conductor. Thus, for example, in some of the embodiments illustrated in
For purposes of the following description, the at least two wellbore casings may be referred to as casing a and casing b. In certain embodiments, sensor measurements are generated indicative of coordinates of the centers of the casings a and b at various depths or positions along the conductor. In certain such embodiments, the coordinates are north and east coordinates; the measurements generated for casing a are generated at substantially the same depths as they are for casing b; and these depths are substantially equally spaced along the conductor. In certain embodiments, these measurements are the principal inputs to the following algorithm. If there are n+1 location measurements for each casing generated at n+1 depths x0, x1, . . . , xn along the conductor, then, for each i such that 0≦i≦n, the ith position xi can be referred to as station i, where the depth of the stations increases as i increases. The location of each of casings a and b at the initial depth x0 (station 0) constitutes a reference point to which subsequent measurements are related. These inputs can be represented by an (n+1)×4 matrix C:
where, for each i such that 0≦i≦n, Na(i) and Nb(i) are the north coordinates of casings a and b at station i, respectively, and Ea(i) and Eb(i) are the east coordinates of casings a and b at station i, respectively, with station 0 being the hang-up point and station n being the last or lowest joint survey station. In some embodiments, the coordinates at station 0 are measured directly with high accuracy surface tools and can be considered error-free compared to the other coordinates, which are measured with downhole survey tools.
The fixed, starting or initial-depth casing-center-to-casing-center distance d(0) is given by
d(0)=√{square root over ((Nb(0)−Na(0))2+(Eb(0)−Ea(0))2)}{square root over ((Nb(0)−Na(0))2+(Eb(0)−Ea(0))2)}{square root over ((Nb(0)−Na(0))2+(Eb(0)−Ea(0))2)}{square root over ((Nb(0)−Na(0))2+(Eb(0)−Ea(0))2)}, (Eq. 13)
and the casing-center-to-casing-center distance matrix d is given by
where, for each i such that 1≦i≦n,
da,b(i)=√{square root over ((Nb(i)−Na(i))2+(Eb(i)−Ea(i))2)}{square root over ((Nb(i)−Na(i))2+(Eb(i)−Ea(i))2)}{square root over ((Nb(i)−Na(i))2+(Eb(i)−Ea(i))2)}{square root over ((Nb(i)−Na(i))2+(Eb(i)−Ea(i))2)}. (Eq. 15)
If C is written as C=(ci,j) (with 0≦i≦n and 1≦j≦4), then, for each i such that 1≦i≦n, the formula for da,b(i) becomes
da,b(i)=√{square root over ((ci,3−ci,1)2+(ci,4−ci,2)2)}{square root over ((ci,3−ci,1)2+(ci,4−ci,2)2)}. (Eq. 16)
The n distances da,b(1), . . . , da,b(n) are calculated from potentially erroneous coordinates and will accordingly be potentially erroneous. The errors in the calculated distances may cause the calculated distances to be inconsistent with the physical limitations on the true center-to-center distances imposed by the geometry of the conductor and/or the casings. For example, there is a nonzero minimum center-to-center distance because the casings cannot overlap, and there is a maximum center-to-center distance because the casings must remain in the conductor's interior. Thus, as indicated above, in certain embodiments, the algorithm utilizes geometric constraints on da,b(i) for each i such that 1≦i≦n:
Dmin≦da,b(i)≦Dmax, (Eq. 17)
where Dmin represents the minimum possible center-to-center distance and Dmax represents the maximum possible center-to-center distance. Methods of calculating Dmin and Dmax have been described above.
Certain standard least squares adjustment (LSA) techniques are generally designed to minimize the squared sum effect of residual errors by correcting individual input measurements. However, such methods are only available for unique constraints in the mathematical model of the system. In certain embodiments in which the casings are run into guided conductors, the geometric constraints used are known. In other embodiments, including embodiments in which the casings are unguided, the constraints are non-unique and therefore cannot be used directly with what might be considered “standard” LSA techniques. In these embodiments, this problem can be overcome by utilizing the statistical expectation of da,b(i), denoted e(da,b(i)), which, in certain such embodiments is a good estimate for the true center-to-center distance. In certain such embodiments, due to the elastic properties of the two casings, e(da,b(i)) can be described as a continuous and differentiable function ƒd
e(da,b(i))=ƒd
where 1≦i≦n and, as above, xi denotes station i. As previously indicated, in certain embodiments, generating these unique geometric constraints allows certain LSA techniques to be used.
In certain embodiments, the function ƒd
Thus, certain embodiments involving an LSA technique use a model of the center-to-center distance between casings a and b. In certain such embodiments, a model in which the center-to-center distance is constant is unlikely to be suitable unless the casings are free-hanging and parallel, which only occurs in relatively few cases. In certain embodiments, a more sophisticated mathematical model is advantageously used for the more likely situation in which the conductor is not precisely vertical and the two casings are expected to follow a catenary curve downwards until they reach the conductor's lower side and then rest on the lower side for the remaining distance along the conductor. In certain such embodiments, a continuous model that is differentiable at the position along the conductor at which the casings touch one another and/or reach the lower side of the conductor (the “meeting point”) and whose first order derivative at that position is continuous is advantageously used. For example, in certain embodiments, if the model is a piecewise function indicating a constant center-to-center distance at and below the meeting point, the model advantageously indicates a center-to-center distance above the meeting point that is defined by a quadratic expression whose graph is a parabola reaching a minimum at the meeting point. The quadratic expression thus has a first order derivative equal to zero at the meeting point, which coincides with the first order derivative of a constant function, meaning that the piecewise function has a continuous first order derivative at the meeting point equal to zero. The quadratic portion of such a model also advantageously is a reasonable approximation of the catenary curve the casings are expected to follow initially. For short or moderate arc lengths, this advantageously implies that the quadratic is a reasonable approximation of the center-to-center distance as the casings initially follow the expected catenary trajectories. Thus, in certain embodiments, the center-to-center distance is modeled with the aid of the following function or mapping:
where x is position along the conductor scaled in terms of station numbers (i.e., x is position along the conductor in a given unit (e.g., meters) divided by the distance (e.g., in meters) between successive survey stations); t is the unknown position along the conductor in terms of station numbers of the meeting point; τ is the number of the station nearest to t; and K is an unknown proportionality factor.
In certain embodiments, the magnitude of typical survey errors is large enough to mask the trend of the center-to-center distance. In certain such embodiments, signal-to-noise ratio is improved before the center-to-center model is derived. Analysis of the most significant survey errors has indicated a linear, depth-dependent trend as predominant. Therefore, in certain such embodiments, the signal-to-noise ratio is improved by estimating the contribution made by survey errors to the center-to-center distance calculations and correcting for them. In certain such embodiments, a high degree in precision is not needed in this process, and, in some of these embodiments, it will be sufficient to rotate the center-to-center distance graph around the fixed initial d(0) so that the distance at the last station (i=n) becomes equal to the minimum allowed distance (Dmin). A physical model of the center-to-center distance with sufficient accuracy to serve as a starting point for a later LSA process is then established in certain embodiments through the following procedure:
Once steps are thus taken to improve signal-to-noise ratio, n apparent constraints for use with LSA techniques are given by:
e(da,b(i))=Dmin+K(t−i)2, for i such that 1≦i≦τ, (Eq. 24)
e(da,b(i))=Dmin, for i such that τ≦i≦n, and (Eq. 25)
d(0)=Dmin+Kt2, (Eq. 26)
where e(da,b(i)) is the expectation of da,b(i) and t and K are unknowns.
The relationship between t and K is nonlinear. In certain embodiments, a linearization is performed to create an equation system to be used in conjunction with LSA techniques. In certain such embodiments, the fundamental linearized equation system, in matrix form, can be written as:
e(d)=−A·X−F. (Eq. 27)
The right-hand side of Equation (27) is derived from the apparent constraints; in particular,
A is an (n+1)×2 matrix, with
F is an (n+1)×1 matrix, with
The left-hand side of Equation (27) involves the expectation of the center-to-center distances. In certain embodiments, these distance values are less appropriate as inputs to LSA techniques due to significant but unknown station-to-station correlation effects. In certain such embodiments, these values are easily converted into differences between the center-to-center distances at consecutive stations, which are less correlated. For example, in certain such embodiments, the following coordinate-based differences are defined: for each i such that 1≦i≦n:
δ1(i)=Na(i)−Na(i−1)=ci,1−ci-1.1; (Eq. 31)
δ2(i)=Nb(i)−Nb(i−1)=ci,3−ci−1,3; (Eq. 32)
δ3(i)=Ea(i)−Ea(i−1)=ci,2−ci−1,2; and (Eq. 33)
δ4(i)=Eb(i)−Eb(i−1)=ci,4−ci−1,4. (Eq. 34)
Then, in such embodiments, the da,b(i) are replaced with d(i) as the basis for input to an LSA technique, where for each i such that 1≦i≦n,
Then, for each i such that 1≦i≦n,
for some error terms εk(j).
These center-to-center distance expectation expressions are non-linear. Therefore, in certain embodiments, these expressions will also be linearized. In certain such embodiments, this linearization can be written as:
e(d)=B·ε+M, (Eq. 37)
where
ε=[ε1(1) . . . ε1(n)ε2(1) . . . ε2(n)ε3(1) . . . ε3(n)ε4(1) . . . ε4(n)]T, (Eq. 38)
with T denoting the matrix transpose operation,
and where B is an n×4n matrix composed of four lower triangular n×n submatrices: in particular,
Setting G=M+F and combining Equation (37) with Equation (27) yields:
B·ε+A·X+G=0. (Eq. 45)
Equation system (45) is a redundant system, which can be solved with LSA methods. Advantageously, the “correlate with element adjustment” LSA method is used; this LSA technique is described in detail in several references, including Wells, D. E. & Krakiwsky, E. J., “The Method of Least Squares,” Lecture Notes Vol. 18 (Department of Geodesy and Geomatics Engineering, University of New Brunswick, May 1971, latest reprinting February 1997), particularly pages 113-116, the entirety of which is hereby incorporated by reference.
The correlate with element adjustment technique includes iterations to compensate for imperfection in the linearization process. In certain embodiments, certain steps are iterated until convergence is reached for a value of t, the meeting point. For example, in certain embodiments the following steps are iterated as described below until convergence is reached:
In certain embodiments, once convergence has been reached for τ and, thus, an initial value of t, the following steps are iterated as described below until convergence is reached:
Each of the processes, components, and algorithms described above can be embodied in, and fully automated by, code modules executed by one or more computers or computer processors. The code modules can be stored on any type of computer-readable medium or computer storage device. The processes and algorithms can also be implemented partially or wholly in application-specific circuitry. The results of the disclosed processes and process steps can be stored, persistently or otherwise, in any type of computer storage. In one embodiment, the code modules can advantageously execute on one or more processors. In addition, the code modules can include, but are not limited to, any of the following: software or hardware components such as software object-oriented software components, class components and task components, processes methods, functions, attributes, procedures, subroutines, segments of program code, drivers, firmware, microcode, circuitry, data, databases, data structures, tables, arrays, variables, or the like.
Various embodiments have been described above. Although described with reference to these specific embodiments, the descriptions are intended to be illustrative and are not intended to be limiting. Various modifications and applications may occur to those skilled in the art without departing from the true spirit and scope of the invention as defined in the appended claims.
Number | Name | Date | Kind |
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3735129 | Montgomery et al. | May 1973 | A |
3847215 | Herd | Nov 1974 | A |
5655602 | Collins | Aug 1997 | A |
7117605 | Ekseth et al. | Oct 2006 | B2 |
Number | Date | Country |
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WO 2004070159 | Aug 2004 | WO |
WO 2009014838 | Jan 2009 | WO |
Entry |
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Hicks, S., et al., “Magnus: Utilisation of Conductor Sharing Wellhead Technology to Access Additional Hydrocarbons via a Slot-Constrained Platform”, dated Sep. 8, 2009, in 10 pages. |
International Search Report and Written Opinion issued in related application No. PCT/US2009/067213, on May 13, 2011, in 8 pages. |
Wells D.E. & Krakiwsky E.J., “The Method of Least Squares,” Lecture Notes vol. 18, Department of Geodesy and Geomatics Engineering, University of New Brunswick, May 1971, pp. 113-116. |
Mexican Office Action for Mexican Application No. MX/a/2009/013524 dated Oct. 12, 2012. |
Number | Date | Country | |
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20110067859 A1 | Mar 2011 | US |