Claims
- 1. A method for determining the distance from a borehole to a nearby, substantially parallel target well, comprising:
- positioning a magnetic field sensor at a first depth within a partially drilled borehole to detect x, y, and z components of magnetic fields at the location of said sensor;
- placing a solenoid in a target well;
- energizing the solenoid to produce a magnetic field in the earth surrounding the target well and the borehole;
- positioning said energized solenoid in said target well at locations above and below a plane perpendicular to said borehole at said first depth;
- measuring at said sensor the magnitude of the x, y, and z components of said solenoid magnetic field at selected locations of said solenoid to identify magnetic field maximum values on opposite sides of said plane;
- measuring the depth of said solenoid in said target well for each magnetic field maximum value; and
- determining the difference between the depths of said solenoid at each of said field maximum values, which difference is equal to the lateral distance between said sensor in said relief borehole and said solenoid in said target well at said first depth.
- 2. A method for determining the lateral distance r between two spaced wells, comprising:
- positioning a magnetic field sensor at a first depth in a first well;
- positioning a solenoid in a second well adjacent and generally parallel to said first well;
- energizing said solenoid to produce a magnetic field in the earth surrounding said first and second wells;
- measuring said magnetic field at said sensor .[.for.]. at two depths z.sub.1 and z.sub.2 of said solenoid along the axis of said second well to determine at each depth the lateral component S.sub.r and the axial component S.sub.z of said solenoid magnetic field at said first well;
- obtaining the ratio S.sub.r /S.sub.z at each of said two depths z.sub.1 and z.sub.2 in said second well to provide two corresponding values .alpha..sub.1 and .alpha..sub.2 from the relationship: ##EQU11## determining the lateral distance r between said wells where ##EQU12##
- 3. The method of claim 2, further including determining the value of the magnetic momentum m of said solenoid magnetic field from one of the equation: to permit determination of the lateral distance r at any given depth with a single measurement of said solenoid magnetic field components S.sub.r and S.sub.z from such selected depth by further determining the value of the ratio z/r from the relationship ##EQU13## determining the lateral distance r from one of the relations ##EQU14##
- 4. The method of claim 2, further including selecting said depths z.sub.1 and z.sub.2 to produce values of approximately +1 and -1, respectively, for the ratio S.sub.r /S.sub.z.
- 5. A method of determining the lateral distance r between two spaced wells, comprising: determining empirically the magnetic moment m of a solenoid;
- positioning a magnetic field sensor at a depth z in a first well;
- positioning said solenoid in a second well adjacent and generally parallel to said first well;
- energizing said solenoid to produce a magnetic field in the earth surrounding said first and second wells;
- measuring said magnetic field at said sensor said first depth to determine the lateral component S.sub.r and the axial component S.sub.z of said solenoid magnetic field at said first well;
- determining the ratio S.sub.r /S.sub.z ;
- determining the value of the ratio z/r from the relationship ##EQU15## determining the lateral distance r from one of the relations: ##EQU16##
- 6. A method for determining the .[.distance and.]. direction from a first well to a second well, comprising: lowering a sensor tool including a magnetometer and orienting means to a first depth in a first well;
- lowering a solenoid having a known magnetic moment m into a second well to a known depth z with known inclination and known axial direction .[.m.]. .Iadd.m.Iaddend.;
- energizing said solenoid to produce a target solenoid magnetic field S in the earth surrounding said first and second wells;
- measuring at said sensor tool three vector components S.sub.x ', S.sub.y ' and S.sub.z ' of the target solenoid magnetic field S at the sensor tool; and
- determining from said target solenoid magnetic field components at said sensor the direction from said first well to said second well.
- 7. The method of claim 6, wherein the step of determining the direction from said first well to said second well comprises:
- determining the quantity .[.S.sub.z '=S.circle-solid.m.]. .Iadd.S.sub.z '=S.circle-solid.m.Iaddend.;
- determining a separation unit vector which is the component of the target solenoid field S which is perpendicular to m from the equation ##EQU17## determining the value of the solenoid magnetic field component S.sub.r ' which is perpendicular to the axial direction .[.m as follows.]. .Iadd.m as follows:.Iaddend.
- .[.S=S.sub.z 'm+S.sub.r '.]. .Iadd.S=S.sub.z 'm+S.sub.r '.Iaddend.
- determining the ratio z'/r' as follows: ##EQU18## determining the separation r' of the solenoid from the sensor tool from ##EQU19## where .mu..sub..sigma. is 4.pi. 10.sup.-7 ; and determining the spatial vector R representing the distance and direction from the solenoid to the sensor tool from
- R=r'.vertline.+(z'/r'.vertline.
- 8. A method for determining the distance and direction from a first well to a second well, comprising:
- lowering a sensor tool including a magnetometer and orienting means to a fist depth in a first well;
- lowering a solenoid into a second well to a first known depth z.sub.1 ' with known inclination and known direction;
- energizing said solenoid to produce a target magnetic field in the earth surrounding said first and second wells;
- repositioning said energized solenoid at a second known depth z.sub.2 ' within said second well;
- measuring at said sensor tool three vector components S.sub.x, S.sub.y and S.sub.z of said target S to obtain magnetic field vectors S.sub.1 ' and S.sub.2 ' at each of said first and second depths z.sub.1 ' and Z.sub.2 ';
- determining the quantities ##EQU20## where m is the magnetic moment of the solenoid; determining separation unit vector .[..]. .Iadd.r' which is the part of the target solenoid field vectors S.sub.1 or S.sub.2 which is perpendicular to .[.m.]. .Iadd.m at said first and second depths from the equations ##EQU21## determining the values of the solenoid magnetic field components S.sub.1r ' and S.sub.2r ' which are perpendicular to the axial direction .[.m.]. .Iadd.m.Iaddend. as follows: ##EQU22## determining the ratios z.sub.1 '/r' and z.sub.2 '/r' as follows: ##EQU23## determining the separation r' of the solenoid from the sensor tool from: ##EQU24## determining the spatial vector R representing the distance and direction from one of the solenoid locations to the sensor tool from:
- .[.R.sub.r =r'+(z.sub.1 '/r').]. .Iadd.R.sub.1 =r'(r'+(z.sub.1 '/r')z')..Iaddend.
- 9. The method of claim 8, further including:
- determining the magnetic moment m from the relationship ##EQU25## determining the spatial vector R of the solenoid from the sensor tool at any depth from the relation:
- .[.R=r'.vertline.+(z'/r').]. .Iadd.R.sub.1 =r'(r'+(z.sub.1 '/r')z')..Iaddend.
- 10. The method of claim 6, wherein the step of determining direction includes determining the orientation of said magnetometer within said first well at said first depth;
- measuring the vector components of said magnetic field at said magnetometer and determining a direction from said first well to said second well relative to said magnetometer; and
- determining from the orientation of said magnetometer and the relative direction of said second well the actual direction of said second well from said first well.
- 11. A method for determining the distance from a borehole to a nearby, substantially parallel well, comprising:
- positioning an MWD directional drilling system at a first depth within a borehole said drilling system having a sensor to detect vector components of magnetic fields at said first depth;
- measuring components of the earth's apparent magnetic field at said sensor;
- supplying a DC current reversible between first and second directions to electrically conductive material in a nearby target well to produce a reversible magnetic field superimposed on the earth's magnetic field;
- measuring, during a first time interval, vector components of the total magnetic field at said sensor with said direct current in said first direction;
- measuring, during a second time interval, vector components of the total magnetic field at said sensor with said direct current in said second direction; and
- determining, from differences between measurements of magnetic field vector components at said first and second intervals, the distance between said borehole and said well at said first depth.
- 12. The method of claim 11, further including:
- measuring .[.at said sensor.]. vector components of the earth's gravity; and
- determining, from said components of said direct current magnetic field and said vector components of gravity, the direction from said sensor to said target well.
- 13. Apparatus for measuring the distance and direction between points in two boreholes extending into the earth, comprising:
- a solenoid deployed at a first selected point in a first borehole, said first borehole having a known inclination and direction at said selected point;
- means energizing said solenoid to generate a characteristic known solenoid magnetic field;
- a magnetic field sensor deployed at a second selected point in said second borehole, said field sensor including means measuring three vector components of said characteristic solenoid magnetic field at said second point;
- orientation means to determine the spatial orientation of said magnetic field sensor at said second point in said second borehole; and
- means responsive to said spacial orientation of said sensor and to said measured vector components at said second point in said second borehole and further responsive to said characteristic known solenoid magnetic field to determine the distance and direction between said first and second points.
- 14. The apparatus of claim 13, wherein said magnetic field sensor and said orientation means are carried by a measurement while drilling downhole instrument.
- 15. The apparatus of claim 14, wherein said sensor comprises a magnetometer.
- 16. A method for measuring the distance and direction between points in two boreholes extending into the earth, comprising:
- determining inclination and direction of a first borehole;
- deploying a solenoid at a first selected point in said first borehole;
- energizing the solenoid to generate a characteristic solenoid magnetic field;
- deploying a magnetic field sensor at a second selected point in a second borehole;
- measuring with said magnetic field field sensor three vector components of the characteristic solenoid magnetic field produced in said second borehole by energization of said solenoid;
- determining the spacial orientation of the magnetic field sensor in said second borehole; and
- determining from the generated solenoid characteristic field, from the measured magnetic field components, and from said spacial orientation and said inclination and direction determinations the distance and direction between the solenoid and the magnetic field sensor at said first and said second points, respectively.
- 17. The method of claim 11, wherein the step of determining the distance between said borehole and said well includes measurement of magnetic field components at said sensor prior to supplying said DC current and measurement of magnetic field components at said sensor during the supplying of DC current.
- 18. A method for determining the distance from a borehole to a nearby substantially parallel well in a plane substantially perpendicular to said borehole, comprising:
- positioning at a first depth within a borehole a magnetic field sensor for detecting x and y vector components of magnetic fields at said first depth;
- measuring during a first time interval, x and y vector components of the earth's magnetic field at said sensor;
- thereafter supplying .[.at.]. .Iadd.to electrically conductive material in .Iaddend.said well a D.C. current .[.reversible between first and second directions.]. .Iadd.to produce a magnetic field superposed on the earth's magnetic field.Iaddend.;
- measuring, during a second time interval the x and y vector components of the earth's apparent magnetic field at said sensor with said D.C. current flowing in .[.said.]. .Iadd.a .Iaddend.first direction;
- determining the differences between said earth's magnetic field components and said earth's apparent magnetic field components measured during said first and second time intervals; and
- determining from said differences the distance between said borehole and said well at said first depth.
- 19. The method of claim 18, further including:
- measuring, during a third time interval, x and y vector components of the earth's apparent magnetic field at said sensor with said D.C. current in .[.said.]. .Iadd.a .Iaddend.second direction; and
- determining the differences between said earth's magnetic field vector components and said apparent magnetic field vector components measured during said first and third time intervals.
- 20. The method of claim 19, wherein the step of determining the distance between said borehole and said well includes determining the strength of the target magnetic field vectors at said sensor during said first and third intervals.
- 21. A method for determining the distance from a relief borehole to a target well, comprising:
- lowering a magnetic field sensor into a partially drilled relief borehole;
- fixing the sensor at a first depth within the borehole;
- lowering a solenoid into a target well;
- energizing the solenoid with a low-frequency alternating current to produce an alternating magnetic field in the earth surrounding the target well and the relief borehole;
- moving said energized solenoid vertically in said target well, said solenoid passing through a horizontal plane at said first depth;
- measuring at said sensor the magnitude of the horizontal component of said magnetic field to identify magnetic field maximum values above and below said horizontal plane during the vertical motion of said solenoid;
- measuring the depth of said solenoid in said target well for each magnetic field maximum value; and
- determining the difference between the depths of said solenoid at each magnetic field maximum value, which difference is equal to the distance between said sensor in said relief borehole and said solenoid in said target well at said first depth.
- 22. A method for determining the distance between two spaced wells, comprising:
- lowering fluxgate magnetometers to a first depth in a first well;
- lowering a solenoid into a second wall;
- energizing said solenoid to produce a magnetic field in the earth surrounding said first and second wells;
- moving said energized solenoid along the axis of said second well, said solenoid passing through said first depth during its motion;
- measuring said magnetic field at said magnetometer at a multiplicity of depths of said solenoid along the axis of said second well to determine the maximum magnitudes of the measured magnetic field when said solenoid is above said first depth and when said solenoid is below said first depth; and
- determining the depths of said solenoid when said maximum magnitudes are determined to obtain the horizontal distance between said first and second wells.
- 23. The method of claim 22, wherein the step of determining the distance between said first and second wells includes measuring an upper depth of said solenoid when said magnetic field is at said maximum magnitude above said first depth, and measuring a lower depth of said solenoid when said magnetic field is at said maximum magnitude below said first depth; and
- determining the difference between said upper and lower depths to obtain a direct measurement of said horizontal distance.
- 24. A method for determining the distance and direction from a first well to a second well, comprising:
- lowering a sensor tool including a magnetometer and orienting means to a first depth in a first well;
- lowering a solenoid into a second well;
- energizing said solenoid to produce a target magnetic field in the earth surrounding said first and second wells;
- moving said energized solenoid along the axis of said second well, said solenoid passing through said first depth;
- measuring at said sensor tool the magnitude of said magnetic field at a multiplicity of solenoid depths;
- determining the depths of said solenoid at which the magnitude of the horizontal components of said magnetic field is at a maximum for solenoid locations above and below said first depth to thereby obtain a direct measure of the horizontal distance between said first and second wells at said first depth; and
- determining from said magnetic field at said sensor the direction from said first well to said second well.
- 25. The method of claim 24, wherein the step of determining direction includes determining .[.spaced.]. .Iadd.spacial .Iaddend.orientation of said magnetometer within said first well at said fist depth;
- measuring the horizontal components of said magnetic field at said magnetometer and determining a direction from said first well to said second well relative to said magnetometer; and
- determining from the orientation of said magnetometer and the relative direction of said second well a compass direction to said second well from said first well.
- 26. The apparatus of claim 13, wherein said second selected point is located in a plane passing through said first selected point, said plane being perpendicular to a longitudinal axis of said first borehole.
- 27. The apparatus of claim 13, wherein said means energizing said solenoid comprises means for energizing said solenoid with a reversible direct current.
- 28. The apparatus of claim 27, wherein said first and second selected points .[.line.]. .Iadd.lie .Iaddend.in a plane perpendicular to a longitudinal axis of said first borehole, and further including means for moving said solenoid selectively to third and fourth points on opposite sides of said plane, respectively, for measurements of vector components of said characteristic solenoid magnetic field with said solenoid at said third and fourth points.
- 29. The method of claim 16, wherein the step of energizing the solenoid includes supplying to the solenoid a direct current having a first direction for a first period of time and thereafter supplying to the solenoid a known direct current having a second direction for a second period of time to generate said characteristic solenoid magnetic field, and measuring vector components of said characteristic solenoid magnetic field during said first and second periods of time to obtain a first set of measured vector components.
- 30. The method of claim 16, wherein the step of deploying a magnetic field sensor in a second borehole includes locating the sensor at a selected first depth along the second borehole and wherein the step of deploying a solenoid in a first borehole includes positioning the solenoid along the first borehole at substantially said first depth.
- 31. The method of claim 30, wherein the step of energizing the solenoid includes supplying to the solenoid a direct current having a first direction for a first period of time and thereafter supplying to the solenoid a known direct current having a second direction for a second period of time to generate said characteristic solenoid magnetic field, and measuring vector components of said characteristic solenoid magnetic field during said first and second periods of time to obtain a first set of measured vector components.
- 32. The method of claim 30, further including moving said solenoid a known depth increment to a second depth along said first borehole and thereafter supplying to the solenoid said direct current having said first direction for said first period of time and supplying said direct current having said second direction for said second period of time to obtain a second set of measured vector components, the determination of distance and direction additionally including said second set of measured vector components and said depth increment.
- 33. The method of claim 16, wherein the step of measuring vector components includes measure vector components in a plane perpendicular to the longitudinal axis of said second borehole, and wherein the step of determining distance and direction includes determining the distance and direction along said plane from said sensor to said solenoid. .Iadd.
- 34. The method of claim 6, further including determining the distance from said first well to said second well..Iaddend..Iadd.35. The method of claim 6, further including:
- moving said energized solenoid in said second well; and
- measuring at said sensor tool the magnitude of said magnetic field at solenoid deaths above and below said first depth to obtain a direct measure of the horizontal distance between said first and second wells at said first depths..Iaddend..Iadd.36. A method for determining the direction from a first well to a second well, comprising:
- lowering a sensor tool including a magnetometer and orienting means to a first depth in a first well;
- lowering a solenoid into a second well to a known depth z with known inclination and known axial direction;
- energizing said solenoid to produce a target solenoid magnetic field S in the earth surrounding said first and second wells;
- measuring at said sensor tool vector components S.sub.x and S.sub.y of the target magnetic field S at the sensor tool in an XY plane perpendicular to the axial direction of the solenoid; and
- determining from said vector components at said sensor tool the direction
- from said first well to said second well..Iaddend..Iadd.37. The method of claim 36, further including determining the spacial orientation of said sensor tool; and
- determining the spacial vector R connecting said solenoid and said sensor tool..Iaddend..Iadd.38. The method of claim 36, further including determining the magnetic moment of said solenoid..Iaddend..Iadd.39. The method of claim 36, further including measuring said vector components at
- multiple deaths of said solenoid..Iaddend..Iadd.40. A method for determining the distance from a borehole to a nearby substantially parallel well in a plane substantially perpendicular to the borehole, comprising;
- positioning at a first depth within the borehole a magnetic field sensor for detecting x and y vector components of magnetic fields at said first depth;
- supplying to electrically conductive material in the well a direct current reversible between first and second directions to produce a reversible magnetic field superposed on the earth's magnetic field;
- measuring, during a first time interval the x and y vector components of the earth's apparent magnetic field at said sensor with said direct current flowing in said first direction;
- measuring, during a second time interval the x and y vector components of the earth's apparent magnetic field at said sensor with said direct current flowing in said second direction;
- determining the differences between the earth's apparent magnetic field components measured during said first and second time intervals; and
- determining from said differences the distance between said borehole and said well at said first depth..Iaddend..Iadd.41. The method of claim 40, wherein positioning a magnetic field sensor includes positioning an MWD directional drilling system within said borehole for detecting x, y and z vector components of magnetic fields at said first depth..Iaddend..Iadd.42. The method of claim 41, wherein supplying a direct current to electrically conductive material includes energizing a
- solenoid positioned in the well..Iaddend..Iadd.43. A method for determining the distance from a borehole to a nearby well comprising:
- positioning within the borehole a magnetic field sensor for detecting vector components of magnetic fields;
- supplying to electrically conductive material in the well a direct current reversible between first and second directions to produce a reversible magnetic field superposed on the earth's magnetic field to provide an apparent earth's magnetic field;
- measuring, during a first time interval, x and v vector components of the earth's apparent magnetic field in a plane substantially perpendicular to the well at said sensor with said direct current flowing in said first direction;
- measuring, during a second time interval, the x and v vector components of the earth's apparent magnetic field at said sensor with said direct current flowing in said second direction;
- determining the differences between x and v vector components of the earth's apparent magnetic field measured during said first and second time intervals; and
- determining from said differences the distance between said borehole and said well in a plane substantially perpendicular to said
- well..Iaddend..Iadd.44. The method of claim 43, wherein positioning a magnetic field sensor includes positioning an MWD directional drilling system within said borehole for detecting x, y and z vector components of magnetic fields..Iaddend..Iadd.45. The method of claim 44, wherein supplying a direct current to electrically conductive material includes energizing a solenoid positioned in the well..Iaddend..Iadd.46. Apparatus for determining the lateral distance between two spaced boreholes comprising:
- electrically conductive means deployed in a first borehole having an elongated axis;
- means supplying a reversible DC current to said conductive means to produce a characteristic, known circular magnetic field surrounding said conductive means and said first borehole;
- a magnetic field sensor in a second borehole for measuring at least two vector components of said magnetic field in a plane perpendicular to said axis of said first borehole;
- means for determining the spatial orientation of said sensor; and
- means for determining from said sensor measurements and from said determined spatial orientation the direction, in a plane perpendicular to said axis, from said first borehole to said second
- borehole..Iaddend..Iadd.7. The apparatus of claim 46, further including means for measuring said vector components during a first time interval during which said reversible DC current flows in a first direction in said conductive means, and for measuring said vector component during a second time interval during which said reversible current flows in a second direction in said conductive means, and means for determining from the difference in between measurements made during said first and second intervals the distance between said boreholes..Iaddend.
Parent Case Info
The present application is a continuation-in-part of application Ser. No. 07/972,835 of Arthur F. Kuckes, filed Nov. 6, 1992 and entitled "Movable Solid Source in Target Well For Location Measurement", now abandoned.
US Referenced Citations (20)
Continuation in Parts (1)
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972835 |
Nov 1992 |
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Reissues (1)
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133295 |
Oct 1993 |
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