Patent Grant
7475741
The present invention relates to the field of well drilling guidance and, in particular, to guidance systems that use electromagnetic fields associated with an existing well casing to steer the drilling of a second well proximate to the first.
There is often a need to drill a second well adjacent an existing well. For example, a pair of horizontal wells may be drilled to extract oil from a deposit of heavy oil or tar. Of the pair of wells, an upper well may inject steam into a subterranean deposit of heavy oil or tar while the lower well collects liquefied oil from the deposit. The pair of wells are to be positioned within a few meters of each other along the length of the lateral such that the oil liquefied by the steam from the first well is collected by the second well.
There is a long-felt need for methods to drill multiple wells, e.g., a pair of wells, in juxtaposition. Aligning a second well with respect to a first well is difficult. The drilling path of the second well may be specified to be within a few meters, e.g., 4 to 10 meters, of the first well, but held to within a tolerance, for example, of plus or minus 1 meter. Drilling guidance methods and system are needed to ensure that the drilling path of the second well remains properly aligned with the first well along the entire drilling path of the second well.
Surveying the drilling path at successive points along the path is a conventional drilling guidance method. A difficulty with surveying is that a cumulative error arises in the surveyed well path because small errors made at each successive survey point along the well path are introduced into the survey calculation made at subsequent survey points. The cumulative effect of these small errors may eventually cause the drilling path of the second well to drift outside the specified desired ranges of distance or direction relative to the first well.
U.S. Pat. Nos. 6,530,154; 5,435,069; 5,230,387; 5,512,830 and 3,725,777, and Published US Patent Application 2002/0112,856 disclose various drilling guidance methods and systems to provide drilling path guidance and to compensate for the cumulative effect of conventional survey errors. These known techniques include sensing a magnetic field generated by the magnetic properties of a well casing or a magnetic probe introduced into the well. These methods and systems may require the use a second rig or other device in the first well to push or pump down a magnetic signal source device. The magnetic fields from such a source are subject to magnetic attenuation and distortion by the first well casing, and may also generate a relatively weak magnetic field that is difficult to sense from the desired second well drilling path. In view of these difficulties, there remains a long felt need for a method and system to guide the trajectory of a second well such that is aligned with an existing well.
A system and method have been developed to precisely guide the drilling trajectory of a second well in a manner that ensures that the second well is properly aligned with a first well. In one embodiment, a metallic casing in the first well conducts an alternating current that generates an alternating magnetic field in the earth surrounding the first well. This magnetic field is substantially more predictable in magnitude than would be a magnetic field due solely to the static magnetic properties of the first well. The intended drilling trajectory of the second well is within the measurable magnetic field generated by the current in the first well. A magnetic detector is included within the drilling assembly used for boring the second hole. The magnetic detector senses the magnetic field generated by the current in the first well. Values measured of strength and direction of the magnetic field are used to align the trajectory of the drilling assembly drilling the hole for the second well.
The system may be used to guide a second horizontal well being drilled near a first horizontal well to enhance oil production from subterranean reservoirs of heavy oil or tar sands. The two parallel wells are to be positioned one above the other and separated by a certain distance, e.g., within the range of 4 to 10 meters, through a horizontal section of a heavy oil or tar deposit. In one embodiment, the method guides a drilling path so that the second horizontal well is a consistent and short distance from the first well by: (1) causing a known electrical current to flow in the metallic casing or liner (collectively “casing”) of the first well to produce a continuous magnetic field in the region about the first well, and (2) using magnetic field sensing instruments in the second well while drilling to measure and calculate accurate distance and direction information relative to the first well so that the driller can correct the trajectory of the second well and position the second well in the desired relationship to the first well.
In another embodiment the invention is a method to guide a drilling path of a second well in proximity to a first well including: applying a time-varying electrical current to a conductive casing of the first well; from the drilling path of the second well, sensing an electromagnetic field generated by the current in the first well, and guiding the drilling path trajectory of the second well using the sensed electromagnetic field.
The inventive method may be a method to guide the drilling path of a second well in proximity to a first well comprising: drilling a third well towards a distal section of the first well and establishing a conductive path along the third well to the distal section of the first well; forming an electrical circuit comprising an electrical generator, a conductive casing of the first well and the conductive path along the third well, wherein said generator applies a time-varying electrical current to the circuit; from the drilling path of the second well, sensing an electromagnetic field generated by the current in the first well, and guiding the drilling path of the second well using the sensed electromagnetic field.
The invention may also be embodied as a drilling guidance system for guiding a drilling path of a second well in proximity to a first well, said system comprising: a first conductive path extending a length of the first well; a generator of electrical current connected to opposite ends of the first well to apply current to the first conductive path, and a magnetic field sensor in the drilling path of the second well arranged to detect a field strength and direction of an electromagnetic field generated by the current applied to the first conductive path.
A directional survey is made of the first well to map the well and facilitate planning a surface location for a small, vertical borehole 20 which is a third well. This small borehole will nearly intersect 21 the first well at the distal termination end of the first well. The small hole, with a temporary casing installed, preferably of a non-conductive material such as PVC installed, need only to be large enough to accommodate a special electrode 22 to be lowered to the bottom and near to the first casing. The small vertical hole may be similar in size to a water well and may extend a few meters deeper that the first well.
To establish a conductive path in the small well 18, a suitable conductive fluid may be pumped into the well 20. The electrode 22 is lowered into the vertical hole to provide a current path through the small well. The electrode 22 electrically connects the casing or liner 18 of the first well to a conductive path, e.g. a wire, in the small bore hole 20.
An above ground conductive path, e.g., wires 24, connects the surface ends of the third well 20 and the casing or liner 18 of the first well 10 to an alternating-current (AC) electrical generator 26. The electrical power from the generator drives a current 28 that flows through the wire 24, third well 20, electrode 22, casing or liner of the first well 18 and to the generator.
The alternating-current 28 induces an electromagnetic field 30 in the earth surrounding the casing 18 of the first well. The characteristics of an electromagnetic field from an AC conductive path are well-known. The strength of the electromagnetic field 30 is proportional to the alternating current applied by the generator. The magnitude of current in the casing may be measured with precision by an amp meter, for example. Because the strength of the magnetic fields is proportional to the current, there is a well-defined relationship between the current, measured magnetic field strength at the new well and the distance between the new well and casing of the first well. The strength and direction of the magnetic field are indicative of the distance and direction to the casing of the first well.
The acceptable drilling path of the second well is defined by an acceptable zone 32 that is shown in cross-section in
The drilling trajectory for the second well should remain in the acceptable zone 32 for the entire length of the horizontal portion of the two wells. The drilling guidance system, which includes the sensor assembly 40, is used to maintain the drilling trajectory of the second well within the acceptable zone. Whether the drilling trajectory of the second well 12 is within the acceptable zone 32 is determined based on the direction and strength of the electromagnetic field 30 along the second well path as sensed by the magnetic sensor assembly 40. Measurements of the field intensity and field direction by the sensor assembly 40, in the second well provide information sufficient to determine the direction to the first well and the distance between the two wells. This information is provided to the driller in a convenient form so that he can take appropriate action to maintain the trajectories of the two wells in the proper relationship. The sensor assembly 40 is incorporated into the down hole probe of a wireline steering tool or MWD system for drilling the second well 12. The sensor assembly thus guides the drilling of the second well for directional control of the drill path trajectory.
As current flows in the conductive casing 18 of the first well, the quasistatic or alternating electromagnetic fields produced in the region surrounding the conductor are predictable in terms of their field strength, distribution and polarity. The magnetic field (B) produced by a long straight conductor, such as the well casing, is proportional to the current (I) in the conductor and inversely proportional to the perpendicular distance (r) from the conductor. The relationship between magnetic field, current and distance is set forth in Biot-Savart's Law which states:
B=utI/(2Πr)
Where ut is the magnetic permeability of the region surrounding the conductor and is constant. The distance (r) of the second bore hole from the casing of the first well can thus be determined based on the measurement of the current (I) in the casing and the magnetic field strength (B) at the second bore hole.
The sensor assembly 40 also includes standard orientation sensors (three orthogonal magnetometers 48 and three orthogonal accelerometers 51, and three orthogonal alternating-field magnetic sensors 44, 46, 52 for detection of the electro magnetic field about the first (reference) well. The magnetic sensors, have a component response pattern and are most sensitive to alternating magnetic field intensity corresponding to the frequency of the alternating current source. These sensors are mounted in a fixed relative orientation in the housing for the sensor assembly.
A pair of radial component-magnetic sensors 44 and 46 (typically two or three sensors) are arranged in the probe assembly 40 such that their magnetically sensitive axes are mutually orthogonal. Each component sensor 44, 46 measures the relative magnetic field (B) strengths at the second well. The sensors will each detect different field strengths due to their orthogonal orientations. The direction on the field (B) may be determined by the inverse tangent (tan−1) of the ratio of the field strength sensed by the radial sensors 44, 46. The frame of reference for the radial sensors 44, 46 is the earth's gravity and magnetic north, determined by the magnetic sensors 48 and the gravity sensors. The direction to the conductor of current is calculated by adding 90 degrees to the direction of the field at the point of measurement. The direction from the sensors to the first well and the perpendicular distance between the sensors and the first well, provides sufficient information to guide the trajectory of the second well in the acceptable zone 32.
While the invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not to be limited to the disclosed embodiment, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.
| Number | Name | Date | Kind |
|---|---|---|---|
| 3725777 | Robinson et al. | Apr 1973 | A |
| 4072200 | Morris et al. | Feb 1978 | A |
| 4458767 | Hoehn, Jr. | Jul 1984 | A |
| 4465140 | Hoehn, Jr. | Aug 1984 | A |
| 4593770 | Hoehn, Jr. | Jun 1986 | A |
| 5064006 | Waters et al. | Nov 1991 | A |
| 5155916 | Engebretson | Oct 1992 | A |
| 5230387 | Waters et al. | Jul 1993 | A |
| 5398421 | Nicolle et al. | Mar 1995 | A |
| 5435069 | Nicholson | Jul 1995 | A |
| 5452518 | DiPersio | Sep 1995 | A |
| 5512830 | Kuckes | Apr 1996 | A |
| 5564193 | Brooks | Oct 1996 | A |
| 5923170 | Kuckes | Jul 1999 | A |
| 6152246 | King et al. | Nov 2000 | A |
| 6530154 | Towle | Mar 2003 | B2 |
| 6608565 | Van Steenwyk et al. | Aug 2003 | B1 |
| 6651496 | Van Steenwyk et al. | Nov 2003 | B2 |
| 6927741 | Brune et al. | Aug 2005 | B2 |
| 20020112856 | Van Steenwyk et al. | Aug 2002 | A1 |
| 20030041661 | Van Steenwyk et al. | Mar 2003 | A1 |
| 20030220743 | Van Steenwyk et al. | Nov 2003 | A1 |
| 20040159466 | Haugen et al. | Aug 2004 | A1 |
| 20040160223 | McElhinney | Aug 2004 | A1 |
| Number | Date | Country | |
|---|---|---|---|
| 20060113112 A1 | Jun 2006 | US |
