US3458853A - Underwater guidance method and apparatus - Google Patents

Underwater guidance method and apparatus Download PDF

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US3458853A
US3458853A US659186A US3458853DA US3458853A US 3458853 A US3458853 A US 3458853A US 659186 A US659186 A US 659186A US 3458853D A US3458853D A US 3458853DA US 3458853 A US3458853 A US 3458853A
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acoustical
pulses
pulse
wellhead
drill string
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US659186A
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Charles K Daniels
John P Mccarthy
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PerkinElmer Inc
E G AND G Inc
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EG&G Inc
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    • EFIXED CONSTRUCTIONS
    • E21EARTH OR ROCK DRILLING; MINING
    • E21BEARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B41/00Equipment or details not covered by groups E21B15/00 - E21B40/00
    • E21B41/0007Equipment or details not covered by groups E21B15/00 - E21B40/00 for underwater installations
    • E21B41/0014Underwater well locating or reentry systems
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01SRADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
    • G01S15/00Systems using the reflection or reradiation of acoustic waves, e.g. sonar systems
    • G01S15/02Systems using the reflection or reradiation of acoustic waves, e.g. sonar systems using reflection of acoustic waves
    • G01S15/06Systems determining the position data of a target
    • G01S15/46Indirect determination of position data
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01SRADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
    • G01S15/00Systems using the reflection or reradiation of acoustic waves, e.g. sonar systems
    • G01S15/87Combinations of sonar systems
    • G01S15/876Combination of several spaced transmitters or receivers of known location for determining the position of a transponder or a reflector
    • GPHYSICS
    • G10MUSICAL INSTRUMENTS; ACOUSTICS
    • G10KSOUND-PRODUCING DEVICES; METHODS OR DEVICES FOR PROTECTING AGAINST, OR FOR DAMPING, NOISE OR OTHER ACOUSTIC WAVES IN GENERAL; ACOUSTICS NOT OTHERWISE PROVIDED FOR
    • G10K11/00Methods or devices for transmitting, conducting or directing sound in general; Methods or devices for protecting against, or for damping, noise or other acoustic waves in general
    • G10K11/18Methods or devices for transmitting, conducting or directing sound
    • G10K11/26Sound-focusing or directing, e.g. scanning
    • G10K11/28Sound-focusing or directing, e.g. scanning using reflection, e.g. parabolic reflectors

Definitions

  • This invention relates to guidance methods and apparatus and more particularly to a method and apparatus for guiding equipment from a vessel positioned on the surface of a body of water to an underwater wellhead and finds particular utility in guiding drill strings into submarine wellheads.
  • drilling crews In drilling underwater oil wells, drilling crews often remove drill strings from and reinsert them into submarine wellheads and lower other equipment to these wellheads. In the past they used conduits, guide lines and other means extending from the drilling platform to the submarine wellhead, but these means have not been completely satisfactory. Quite often the conduit has been removed from the wellhead and is not available for reentry. If guide lines break reentry is impossible until they have been reinstalled.
  • a subsidiary object is to provide such a method and apparatus which shall be thoroughly reliable in operation and easily mastered by members of a drilling crew.
  • a funnel-shaped vessel having a large opening with its smaller opening affixed to the top of a submarine wellhead.
  • This vessel may be shaped like a frustrum of a right regular pyramid, a frustrum of a right circular cone, part of a paraboloid of revolution, or part of a hyperboloid of revolution, or it may be a trihedral corner reflector with the corner cut off.
  • Disposed within the funnel-shaped vessel near the wellhead pipe is an acoustical transponder. When this acoustical transponder receives a first pulse of acoustical energy it radiates a second pulse of acoustical energy.
  • the first pulse of acoustical energy emanates from a pulsed acoustical energy source mounted at the equipment, such as at the lower end of a drill string being lowered into the wellhead.
  • An acoustical receiver such as a hydrophone, located at the ocean platform, receives acoustical pulses impinging upon it and converts them into pulses of electrical energy.
  • the acoustical receiver may, alternately, be located adjacent to the pulsed acoustical energy source, or in drilling operations somewhere between the platform and the equipment, in which case suitable connectors will have to be provided from the acoustical receiver to a suitable time and amplitude display on board the ocean platform.
  • the first pulse of acoustical energy generated by the pulsed acoustical source radiates toward the funnelshaped vessel and transponder, and toward the acoustical receiver located at the ocean platform.
  • the transponder reacts by radiating second pulses of acoustical energy toward the acoustical receiver which converts both the first and second pulses of acoustical energy into pulses of electrical energy.
  • These pulses of electrical energy are displayed on a time base by the time and amplitude display apparatus.
  • the distance between pulses on the display represents the time difference of receipt by the acoustical receiver of the first and second pulses of acoustical energy. When this time dilference is a minimum the drill string is disposed directly over the wellhead.
  • the ocean platform may be maneuvered to obtain the minimum time difference and the equipment or drill string can be lowered while it is a minimum.
  • the funnelshaped vessel may also be a trihedral corner reflector. In this event, when the time dilference is a minimum another pulse will appear upon the display. This is a reflected pulse of acoustical energy received from the reflector. Portions of the first pulses of the acoustical energy generated by the source impinge upon the reflector and are reflected as reflected pulses of acoustical energy toward the source and the acoustical receiver. The ocean platform is then maneuvered until the amplitude of the received reflected acoustical pulse is a maximum.
  • FIGURE 1 is a schematic representation of the invention showing a drill string lowered .a short distance below the ocean platform and out of alignment with the wellhead;
  • FIGURES 7A through 7C illustrate the displays produced when maneuvering the ocean platform according to FIGURE 3, including the display produced when dropping the drill string into the wellhead according to the present invention
  • FIGURES 8 through 13 illustrate funnel-shaped vessels that may be utilized at the wellhead
  • FIGURE 14 illustrates an alternative embodiment of the present invention.
  • FIGURES 15A through 15D illustrate the displays produced with the embodiment of FIGURE 14.
  • FIGURE 1 illustrates ocean platform floating on a body of water.
  • Platform 20 may be a floating vessel, tug, drilling barge, jack-up rig, or the like.
  • Platform 20 supports drill string 22 and acoustical receiver 24 by means well known in the art.
  • Acoustical receiver 24 may be a hydrophone extending three or four feet downwardly from the bottom surface of platform 20.
  • Drill string 22 likewise may extend downwardly through the bottom surface of platform 20. For purposes of explanation, we shall assume that it extends some 40 feet below the end of acoustical receiver 24.
  • Pulsed acoustical energy source 2 6 is installed within the lower end of drill string 22 opposite slots 28 as illustrated in FIGURE 2. It is centered within drill string 22 by spring fingers 27.
  • Pulsed acoustical energy source 26 may take various forms. It may be a magnetostrictive device that generates pulses of acoustical energy when a current is caused to flow through a wire coiled around the magnetostrictive device. Other forms of pulsed acoustical energy may be used, such as electromagnetic or piezoelectric devices. Pulsed acoustical energy source 26 may be self-powered, or may be powered through a cable, not shown, passing through drill string 22 to platform 20. This latter scheme is not preferred in actual practice.
  • Funnel-shaped vessel 32 is mounted directly on wellhead substantially as illustrated in FIGURE 1.
  • Acoustical transponder 34 extends through the bottom surface of funnel-shaped vessel 32, is disposed close to wellhead 30, and is adapted to receive acoustical pulses directly from pulsed acoustical energy source 26.
  • Cable 36 connects acoustical receiver 24 to time and amplitude display apparatus 38 which produces waveforms representing acoustical pulses such as illustrated in FIGURES 4A through 4D and FIGURES 7A through 7C.
  • FIGURE 1 illustrates that a portion of an acoustical energy pulse produced by source 26 travels a distance 40 from the lower end of drill string 22 to acoustical receiver 24 while another portion of the same pulse travels a distance 42 toward transponder 34.
  • a portion of the same pulse travels path 52 to the bottom and back to acoustical receiver 24, as illustrated.
  • the pulse of acoustical energy produced by transponder 34 travels a distance 44 plus distance 40 toward acoustical receiver 24.
  • FIGURES 4A through 4D illustrate schematically the waveforms of electrical pulses produced by acoustical receiver 24 in response to acoustical pulses impinging thereon. To facilitate understanding, the acoustical noise associated with these pulses is not shown.
  • pulse 54 represents that portion of the acoustical pulse produced by source 26 that travels distance 40 to acoustical receiver 24.
  • pulse 56 represents the bottom pulse that travels along path 52.
  • pulse 58 represents the pulse directed by transponder 34 toward acoustical receiver 24.
  • the horizontal distance in FIGURE 4A between pulses 54 and 58 represents .and is proportional to the sum of distances 42 and 44 of FIGURE 1.
  • One-half of the sum of distances 42 and 44 is roughly equal to distance 42 from acoustical source 26 to wellhead 30.
  • platform 20 has been maneuvered so that the horizontal distance between pulses 54 and 58 is somewhat smaller.
  • the distance is still smaller.
  • FIGURE 4D platform 20 has been maneuvered until the distance between pulse 54 and 58 is a minimum. This is equivalent to distance 46 in FIGURE 1.
  • Distance 46 is, of course, the vertical distance between source 26 and Wellhead 30.
  • Ocean platform 20 is usually so moored that it can be maneuvered quite accurately.
  • FIGURE 3 assume that platform 20 is maneuvered in either direction along course 60 while pulses 54 and 58 of FIGURES 4A through 4D are observed on display 38. At some point the horizontal distance between pulses 54 and 58 approaches a minimum. Thereafter this distance begins to lengthen. The direction along course 60 is then reversed for a short distance and a new course taken at approximately right angles to course 60; say, for example, course 62. The same procedure is followed and another course 64 substantially at right angles to course 62 is taken. This is repeated with courses 66, 68, etc. until the point is reached where small course changes in any direction of platform 20 only cause increases in the distance between pulses 54 and 58. Drill string 22 is then vertically aligned with wellhead 30.
  • time and amplitude display apparatus 38 can be so calibrated that the horizontal distance between pulses 54 and 58 is read as one-half the sum of distances 42 and 44 of FIGURE 1. Then, when the vertical distance between the lower end of drill string 22 and wellhead 30 is known, platform 20 can be maneuvered until this distance is read on display apparatus 38.
  • drill string 22 As the drill string is lowered to various heights above wellhead 30, it may be stopped and the foregoing process repeated to confirm the alignment.
  • FIGURE 5 when drill string 22 has been lowered to a vertical distance above wellhead 30 represented by reference number 76, which distance may be 15 or 20 feet above funnel-shaped vessel 32, the same procedure may be repeated until the alignment shown in FIGURE 6 is obtained. If the minimum distance is maintained and if display apparatus 38 has a resolution, for example, within one foot, drill string 22 can be slowly dropped into wellhead 30. However, before doing this it is desirable that the alignment be confirmed by a method now to be described.
  • funnel-shaped vessel 32 is trihedral corner reflector
  • a portion of the acoustical pulse emitted by pulsed acoustical source 26 will impinge upon the surface of the corner reflector.
  • the characteristics of the corner reflector are such that if an acoustical pulse is incident on the active area of the corner reflector,
  • the reflected pulse will be substantially parallel to the incident pulse.
  • the reflected pulse will also be directed toward acoustical receiver 24 as illustrated schematically in FIGURE 5 by path 78 for the incident pulse, path 80 for that portion of the pulse reflected back toward acoustical source 26, and path 82 for that portion of the reflected acoustical pulse that impinges upon acoustical receiver 24.
  • pulse 54 represents the direct acoustical pulse from acoustical source 26 and pulse 58 represents the acoustical pulse from transponder 34.
  • Pulse 84 represents that portion of the reflected acoustical pulse that impinges upon acoustical receiver 24.
  • the lower end of drill string 22 may be maneuvered so that pulse 84 rises in amplitude. Comparing FIG- URE 6 with FIGURE 5, as drill string 22 comes closer in alignment with wellhead 30 and funnel-shaped vessel 32, greater portions of the reflected acoustical pulses will impinge upon acoustical receiver 24 and the amplitude of pulse 84 will increase.
  • pulses 54, 58 and 84 of FIGURE 7C merge together as illustrated.
  • FIGURE 8 illustrates triangular trihedral corner reflector 86 consisting of three reflecting planes perpendicular to each other, assembled to form a right angle corner.
  • a ray incident upon an interior surface of corner reflector 86 is reflected from each of three surfaces successively and returned in a direction parallel to the incident ray.
  • the path of such a ray is shown as ray 100-100.
  • Some rays, upon entering corner reflector 86 are reflected only twice and will go off at an angle oblique the remaining portion being utilized as the corner reflectr or.
  • Corner reflector 110 produces reflected acoustical pulses of somewhat greater amplitude than corner reflector 86 of FIGURE 8.
  • corner 106 of reflectors 86 and 110 may be removed to facilitate entry of drill string 22 into wellhead 30.
  • funnel-shaped vessel 32 may take one of the forms illustrated in FIGURES 10 through 13.
  • funnel-shaped vessel 32 is a frustrum of a right circular cone.
  • FIGURE 11 it is a frustrum of a right regular pyramid.
  • FIGURE 12 it is a paraboloid of revolution with the closed end removed for entry of the drill string.
  • FIGURE 13 it is a hyperboloid of revolution with the closed end likewise removed.
  • the operator may desire to maneuver for a minimum distance between pulses 54 and 58 with the drill string lowered a short distance below the lower end of acoustical receiver 24, making use only of transponder 34.
  • the operator knows the actual distance from the lower surface of platform 20 to the top edge of funnel-shaped vessel 32. In this event, he first maneustring until it is within 15 or 20 feet of the top edge of funnel-shaped vessel 32. In this event, he first maneuvers for a minimum distance between pulses 54 and 58. If funnel-shaped vessel 32 is a trihedral corner reflector he Will then also observe reflected pulse 84. He then maneuvers platform 20 until the amplitude of reflected pulse 84 becomes a maxi-mum. At this point he can drop drill string 22 into wellhead 30 observing the merging of pulses 54, 58 and 84.-
  • FIGURE 14 illustrates an alternative embodiment while FIGURES 15A through 15D illustrate schematically the pulses produced by this embodiment.
  • hydrophone 24 is disposed in the lower end of drill string 22 and is responsive to pulses of acoustical energy approaching from below.
  • a different hydrophone configuration mounted on the exterior surface of drill string 22 could be used as well.
  • Pulsed acoustical source 26 mounts on the lower surface of ocean platform 20. Cables 31 and 83 connect source 26 and hydrophone 24 respectively to time and display apparatus 38.
  • a first pulse of acoustical energy emanating from source 26 travels distance 91 to transponder 34 which reacts by producing a second pulse of acoustical energy, either immediately or at a fixed time later, that travels distance 92 to hydrophone 24.
  • a signal pulse 54' is displayed by time and display apparatus 38 as illustrated in FIGURES 15A through 15D.
  • the second pulse received by hydrophone 24 appears as pulse 58' in the display.
  • the distance between pulses 54' and 58' is proportional to the sum of distances 91 and 92.
  • Platform 20 may then be maneuvered according to the plan of FIGURE 3 to obtain a minimum for the distance between pulses 54' and 58'. The shortening of this distance is illustrated in FIGURES 15A through 15D.
  • a reflected pulse 84' will appear as illustrated in FIGURE 15C.
  • a portion of the first pulses impinge along path 93 on funnel-shaped vessel 32, which, of course, must be a trihedral corner reflector.
  • the reflected acoustical pulse travels path 94 back toward source 26 and a portion travels path 95 toward hydrophone 24 where it is received, converted to an electrical pulse and is displayed as pulse 84'.
  • Drill string 22 will be aligned with wellhead 30 when this minimum distance is achieved and the amplitude of pulse 84' is a maximum. The distance between pulses 58' and 84' will remain fixed as drill string 22 is lowered into wellhead 30.
  • trihedral corner reflectors may be made of material having a thickness equal to onequarter of the wavelength of the frequency of the pulsed acoustical source in the material to assure that acoustical energy reflected from top and bottom surfaces of the material is in phase in the reflected acoustical pulse. Accordingly all such changes are considered to fall within the spirit and scope of the invention.
  • Apparatus for guiding equipment from an ocean platform to a submarine wellhead comprising a trihedral corner reflector located at the wellhead,
  • a first pulsed acoustical source located at a second predetermined point for producing first pulses of acoustical energy, portions of which radiate toward and impinge upon the trihedral corner reflector and are directively reflected toward the first predetermined point as reflected acoustical pulses, portions of which are received by the hydrophone, the equipment being located at one of the predetermined points;
  • transponder so disposed at the trihedral corner reflector as to radiate second pulses of acoustical energy toward the hydrophone at the first predetermined point in response to receipt of portions of the first pulses of acoustical energy
  • the first predetermined point is at the equipment
  • the second predetermined point is at the ocean platform.

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Description

July, 1969 v c, DANlELs ET AL 3,458,853
UNDERWATER GUIDANCE METHOD AND APPARATUS Fil ed Aug. 8. 1967 Y 4 Sheets-Sheet 1 Fig. 3. r
'54 '58 Flg. 4B.
( CHARLES K. DANIELS JOHN P. MCCARTHY Fig. 4 C. INVENTORS T??? I g qzw Fig.4D.
ATTORNEYS July 29, 1969 Q DAMELS ET AL 3,458,853
UNDERWATER GUIDANCE METHOD AND APPARATUS Filed Aug. 8, 1967 4 Sheets-Sheet 2 Fig. .7 B. CHARLES K. DANIELS 54 53 JOHN R MCCARTHY 84 INVENTORS F Fig. TC. BY 2 2 ATTORNEYS July 29, 1969 Q DAN|EL5 ET AL 3,458,853
UNDERWATER GUIDANCE METHOD AND APPARATUS Filed Aug. 8, 1967 4 Sheets-Sheet 5 CHARLES K. DANIELS JOHN R M CARTHY INVENTORS Fig.11. BY Z @4412 ATTORNEYS July 29, 1969 c. K. DANIELS ET L 3,453,353
UNDERWATER GUIDANCE METHOD AND APPARATUS Filed Aug. 9, 1967 Fig. 15A.
Fig. 153. 54 {3 Fig. 150.
p84 ll Fig. 15D.
4 Sheets-Sheet 4 CHARLES K. DANIELS JOHN R MCCARTHY INVENTORS ATTORNEYS United States Patent 3,458,853 UNDERWATER GUIDANCE METHOD AND APPARATUS Charles K. Daniels, Weston, and John P. McCarthy,
Cohasset, Mass., assignors to EG&G International, Inc,
Bedford, Mass., a corporation of Delaware Filed Aug. 8, 1967, Ser. No. 659,186 Int. Cl. G01s 7/52 US. Cl. 340--3 3 Claims ABSTRACT OF THE DISCLOSURE Method and apparatus for guiding equipment, such as a drill string or blow-out preventer stack, from an ocean platform to a submarine wellhead, including producing at the equipment first acoustical pulses which radiate toward the platform and wellhead; producing at the wellhead second acoustical pulses in response to first acoustical pulses received from the equipment, the second acoustical pulses being radiated toward the platform; receiving the first and second acoustical pulses at the platform; measuring the time difference of arrival at the platform of the first and second acoustical pulses; maneuvering the platform until this time difference becomes a minimum; lowering the equipment when this time difference is a minimum; directively reflecting a portion of the first acoustical pulses from the wellhead back toward the equipment and toward the platform as reflected acoustical pulses; receiving part of the reflected acoustical pulses at the platform; maneuvering the platform until the amplitude of the received reflected acoustical pulses becomes a maximum; and lowering the equipment into the wellhead when the amplitude of the received reflected acoustical pulses is a maximum.
Prior art This invention relates to guidance methods and apparatus and more particularly to a method and apparatus for guiding equipment from a vessel positioned on the surface of a body of water to an underwater wellhead and finds particular utility in guiding drill strings into submarine wellheads.
In drilling underwater oil wells, drilling crews often remove drill strings from and reinsert them into submarine wellheads and lower other equipment to these wellheads. In the past they used conduits, guide lines and other means extending from the drilling platform to the submarine wellhead, but these means have not been completely satisfactory. Quite often the conduit has been removed from the wellhead and is not available for reentry. If guide lines break reentry is impossible until they have been reinstalled.
Attempts have also been made to use television cameras and magnetic field indicating means for reentry. Poor visibility caused by particles suspended in the water in and around the wellhead limits the use of a television camera. The magnetic field producing means located at the wellhead is limited by the fact that it depends upon power from either a self-contained generating source or a separate power source located at the surface of the sea.
Objects Accordingly, it is the principal object of this invention to provide a method and apparatus for accurately guiding equipment from an ocean platform to a submarine wellhead.
A subsidiary object is to provide such a method and apparatus which shall be thoroughly reliable in operation and easily mastered by members of a drilling crew.
Further objects and advantages will become apparent hereinafter.
3,458,853 Patented July 29, 1969 Summary of the invention The above objects of the invention are achieved by installing a funnel-shaped vessel having a large opening with its smaller opening affixed to the top of a submarine wellhead. This vessel may be shaped like a frustrum of a right regular pyramid, a frustrum of a right circular cone, part of a paraboloid of revolution, or part of a hyperboloid of revolution, or it may be a trihedral corner reflector with the corner cut off. Disposed within the funnel-shaped vessel near the wellhead pipe is an acoustical transponder. When this acoustical transponder receives a first pulse of acoustical energy it radiates a second pulse of acoustical energy. The first pulse of acoustical energy emanates from a pulsed acoustical energy source mounted at the equipment, such as at the lower end of a drill string being lowered into the wellhead. An acoustical receiver, such as a hydrophone, located at the ocean platform, receives acoustical pulses impinging upon it and converts them into pulses of electrical energy. The acoustical receiver may, alternately, be located adjacent to the pulsed acoustical energy source, or in drilling operations somewhere between the platform and the equipment, in which case suitable connectors will have to be provided from the acoustical receiver to a suitable time and amplitude display on board the ocean platform. The first pulse of acoustical energy generated by the pulsed acoustical source radiates toward the funnelshaped vessel and transponder, and toward the acoustical receiver located at the ocean platform. The transponder reacts by radiating second pulses of acoustical energy toward the acoustical receiver which converts both the first and second pulses of acoustical energy into pulses of electrical energy. These pulses of electrical energy are displayed on a time base by the time and amplitude display apparatus. The distance between pulses on the display represents the time difference of receipt by the acoustical receiver of the first and second pulses of acoustical energy. When this time dilference is a minimum the drill string is disposed directly over the wellhead. The ocean platform may be maneuvered to obtain the minimum time difference and the equipment or drill string can be lowered while it is a minimum. The funnelshaped vessel may also be a trihedral corner reflector. In this event, when the time dilference is a minimum another pulse will appear upon the display. This is a reflected pulse of acoustical energy received from the reflector. Portions of the first pulses of the acoustical energy generated by the source impinge upon the reflector and are reflected as reflected pulses of acoustical energy toward the source and the acoustical receiver. The ocean platform is then maneuvered until the amplitude of the received reflected acoustical pulse is a maximum. This confirms, for example, that the drill string is aligned with the Wellhead and it may be lowered therein. As the drill string approaches very closely to the corner reflector, the first acoustical pulse, the second acoustical pulse and the reflected acoustical pulse all tend to merge. At this point the drill string is entering the wellhead.
The above objects will be readily understood by those skilled in the art by reading the following detailed description of a particular embodiment utilized in exploration coring, oil well drilling, or work over operations. It is to be understood that the invention is not limited to the specific method and apparatus disclosed and described but that it has more general utility.
Description of the drawing FIGURE 1 is a schematic representation of the invention showing a drill string lowered .a short distance below the ocean platform and out of alignment with the wellhead;
tance of the wellhead and in alignment therewith;
FIGURES 7A through 7C, illustrate the displays produced when maneuvering the ocean platform according to FIGURE 3, including the display produced when dropping the drill string into the wellhead according to the present invention;
FIGURES 8 through 13 illustrate funnel-shaped vessels that may be utilized at the wellhead;
FIGURE 14 illustrates an alternative embodiment of the present invention; and
FIGURES 15A through 15D illustrate the displays produced with the embodiment of FIGURE 14.
Detailed description FIGURE 1 illustrates ocean platform floating on a body of water. Platform 20 may be a floating vessel, tug, drilling barge, jack-up rig, or the like. Platform 20 supports drill string 22 and acoustical receiver 24 by means well known in the art. Acoustical receiver 24 may be a hydrophone extending three or four feet downwardly from the bottom surface of platform 20. Drill string 22 likewise may extend downwardly through the bottom surface of platform 20. For purposes of explanation, we shall assume that it extends some 40 feet below the end of acoustical receiver 24. Pulsed acoustical energy source 2 6 is installed within the lower end of drill string 22 opposite slots 28 as illustrated in FIGURE 2. It is centered within drill string 22 by spring fingers 27. During operation pulses of acoustical energy emanate from source 26 through slots 28 toward acoustical receiver 24 and toward wellhead 30. Pulsed acoustical energy source 26 may take various forms. It may be a magnetostrictive device that generates pulses of acoustical energy when a current is caused to flow through a wire coiled around the magnetostrictive device. Other forms of pulsed acoustical energy may be used, such as electromagnetic or piezoelectric devices. Pulsed acoustical energy source 26 may be self-powered, or may be powered through a cable, not shown, passing through drill string 22 to platform 20. This latter scheme is not preferred in actual practice. Funnel-shaped vessel 32 is mounted directly on wellhead substantially as illustrated in FIGURE 1. Acoustical transponder 34 extends through the bottom surface of funnel-shaped vessel 32, is disposed close to wellhead 30, and is adapted to receive acoustical pulses directly from pulsed acoustical energy source 26. Cable 36 connects acoustical receiver 24 to time and amplitude display apparatus 38 which produces waveforms representing acoustical pulses such as illustrated in FIGURES 4A through 4D and FIGURES 7A through 7C.
If a pulse of acoustical energy is produced by pulsed acoustical energy source 26, a portion of this pulse propagates toward acoustical receiver 24 while another portion propagates toward wellhead 30 and funnel-shaped vessel 32. The latter portion is received by transponder 34 which produces another pulse of acoustical energy, either immediately or after a fixed time, a portion of which pulse propagates toward acoustical receiver 24. FIGURE 1 illustrates that a portion of an acoustical energy pulse produced by source 26 travels a distance 40 from the lower end of drill string 22 to acoustical receiver 24 while another portion of the same pulse travels a distance 42 toward transponder 34. Similarly,
a portion of the same pulse travels path 52 to the bottom and back to acoustical receiver 24, as illustrated. The pulse of acoustical energy produced by transponder 34 travels a distance 44 plus distance 40 toward acoustical receiver 24.
FIGURES 4A through 4D illustrate schematically the waveforms of electrical pulses produced by acoustical receiver 24 in response to acoustical pulses impinging thereon. To facilitate understanding, the acoustical noise associated with these pulses is not shown. In FIGURES 4A through 4D pulse 54 represents that portion of the acoustical pulse produced by source 26 that travels distance 40 to acoustical receiver 24. Similarly, pulse 56 represents the bottom pulse that travels along path 52. In FIGURE 4A pulse 58 represents the pulse directed by transponder 34 toward acoustical receiver 24. The horizontal distance in FIGURE 4A between pulses 54 and 58 represents .and is proportional to the sum of distances 42 and 44 of FIGURE 1. One-half of the sum of distances 42 and 44 is roughly equal to distance 42 from acoustical source 26 to wellhead 30. In FIGURE 4B platform 20 has been maneuvered so that the horizontal distance between pulses 54 and 58 is somewhat smaller. Likewise in FIGURE 40 the distance is still smaller. In FIGURE 4D platform 20 has been maneuvered until the distance between pulse 54 and 58 is a minimum. This is equivalent to distance 46 in FIGURE 1. Distance 46 is, of course, the vertical distance between source 26 and Wellhead 30.
Ocean platform 20 is usually so moored that it can be maneuvered quite accurately. Referring to FIGURE 3, assume that platform 20 is maneuvered in either direction along course 60 while pulses 54 and 58 of FIGURES 4A through 4D are observed on display 38. At some point the horizontal distance between pulses 54 and 58 approaches a minimum. Thereafter this distance begins to lengthen. The direction along course 60 is then reversed for a short distance and a new course taken at approximately right angles to course 60; say, for example, course 62. The same procedure is followed and another course 64 substantially at right angles to course 62 is taken. This is repeated with courses 66, 68, etc. until the point is reached where small course changes in any direction of platform 20 only cause increases in the distance between pulses 54 and 58. Drill string 22 is then vertically aligned with wellhead 30.
Obviously time and amplitude display apparatus 38 can be so calibrated that the horizontal distance between pulses 54 and 58 is read as one-half the sum of distances 42 and 44 of FIGURE 1. Then, when the vertical distance between the lower end of drill string 22 and wellhead 30 is known, platform 20 can be maneuvered until this distance is read on display apparatus 38.
As the drill string is lowered to various heights above wellhead 30, it may be stopped and the foregoing process repeated to confirm the alignment. Thus, referring to FIGURE 5, when drill string 22 has been lowered to a vertical distance above wellhead 30 represented by reference number 76, which distance may be 15 or 20 feet above funnel-shaped vessel 32, the same procedure may be repeated until the alignment shown in FIGURE 6 is obtained. If the minimum distance is maintained and if display apparatus 38 has a resolution, for example, within one foot, drill string 22 can be slowly dropped into wellhead 30. However, before doing this it is desirable that the alignment be confirmed by a method now to be described.
Referring to FIGURE 5, if funnel-shaped vessel 32 is trihedral corner reflector, a portion of the acoustical pulse emitted by pulsed acoustical source 26 will impinge upon the surface of the corner reflector. The characteristics of the corner reflector are such that if an acoustical pulse is incident on the active area of the corner reflector,
the reflected pulse will be substantially parallel to the incident pulse. Remembering that drill string 22 is close to alignment with wellhead 30, the reflected pulse will also be directed toward acoustical receiver 24 as illustrated schematically in FIGURE 5 by path 78 for the incident pulse, path 80 for that portion of the pulse reflected back toward acoustical source 26, and path 82 for that portion of the reflected acoustical pulse that impinges upon acoustical receiver 24. Referring now to FIGURES 7A through 7C and ignoring reflected bottom pulses (not shown), pulse 54 represents the direct acoustical pulse from acoustical source 26 and pulse 58 represents the acoustical pulse from transponder 34. Pulse 84 represents that portion of the reflected acoustical pulse that impinges upon acoustical receiver 24. With the same maneuvering as described above with reference to FIG- URE 3, the lower end of drill string 22 may be maneuvered so that pulse 84 rises in amplitude. Comparing FIG- URE 6 with FIGURE 5, as drill string 22 comes closer in alignment with wellhead 30 and funnel-shaped vessel 32, greater portions of the reflected acoustical pulses will impinge upon acoustical receiver 24 and the amplitude of pulse 84 will increase. As the lower end of drill string 22 is then dropped into wellhead 30 pulses 54, 58 and 84 of FIGURE 7C merge together as illustrated. In practice ocean currents may cause the lower end of drill string 22 to sway a distance considerably greater than the length of the top edge of funnel-shaped vessel 32. Hence, it is necessary that pulses 54, 58 and 84 be Watched carefully so that drill string 22 is lowered only when pulse 84 is at a maximum and that the three pulses merge when it is dropped into wellhead 30.
FIGURE 8 illustrates triangular trihedral corner reflector 86 consisting of three reflecting planes perpendicular to each other, assembled to form a right angle corner. In general, a ray incident upon an interior surface of corner reflector 86 is reflected from each of three surfaces successively and returned in a direction parallel to the incident ray. The path of such a ray is shown as ray 100-100. Some rays, upon entering corner reflector 86 are reflected only twice and will go off at an angle oblique the remaining portion being utilized as the corner reflectr or. The same considerations apply to rays impinging on the surfaces of square trihedral corner reflector 110 of FIGURE 9. Corner reflector 110 produces reflected acoustical pulses of somewhat greater amplitude than corner reflector 86 of FIGURE 8. In oil well drilling applications corner 106 of reflectors 86 and 110 may be removed to facilitate entry of drill string 22 into wellhead 30.
In some applications, the corner reflector method of guiding drill string 22 into wellhead 30 may not be used. In these applications funnel-shaped vessel 32 may take one of the forms illustrated in FIGURES 10 through 13. In FIGURE 10, funnel-shaped vessel 32 is a frustrum of a right circular cone. Similarly, in FIGURE 11 it is a frustrum of a right regular pyramid. In FIGURE 12 it is a paraboloid of revolution with the closed end removed for entry of the drill string. In FIGURE 13 it is a hyperboloid of revolution with the closed end likewise removed.
In operation, the operator may desire to maneuver for a minimum distance between pulses 54 and 58 with the drill string lowered a short distance below the lower end of acoustical receiver 24, making use only of transponder 34. However, if the operator knows the actual distance from the lower surface of platform 20 to the top edge of funnel-shaped vessel 32. In this event, he first maneustring until it is within 15 or 20 feet of the top edge of funnel-shaped vessel 32. In this event, he first maneuvers for a minimum distance between pulses 54 and 58. If funnel-shaped vessel 32 is a trihedral corner reflector he Will then also observe reflected pulse 84. He then maneuvers platform 20 until the amplitude of reflected pulse 84 becomes a maxi-mum. At this point he can drop drill string 22 into wellhead 30 observing the merging of pulses 54, 58 and 84.-
Alternate embodiment FIGURE 14 illustrates an alternative embodiment while FIGURES 15A through 15D illustrate schematically the pulses produced by this embodiment. In FIGURE 14, hydrophone 24 is disposed in the lower end of drill string 22 and is responsive to pulses of acoustical energy approaching from below. A different hydrophone configuration mounted on the exterior surface of drill string 22 could be used as well. Pulsed acoustical source 26 mounts on the lower surface of ocean platform 20. Cables 31 and 83 connect source 26 and hydrophone 24 respectively to time and display apparatus 38.
A first pulse of acoustical energy emanating from source 26 travels distance 91 to transponder 34 which reacts by producing a second pulse of acoustical energy, either immediately or at a fixed time later, that travels distance 92 to hydrophone 24. When the first pulse is generated by source 26, a signal pulse 54' is displayed by time and display apparatus 38 as illustrated in FIGURES 15A through 15D. The second pulse received by hydrophone 24 appears as pulse 58' in the display. The distance between pulses 54' and 58' is proportional to the sum of distances 91 and 92. Platform 20 may then be maneuvered according to the plan of FIGURE 3 to obtain a minimum for the distance between pulses 54' and 58'. The shortening of this distance is illustrated in FIGURES 15A through 15D.
At some point during this maneuvering a reflected pulse 84' will appear as illustrated in FIGURE 15C. At this point, a portion of the first pulses impinge along path 93 on funnel-shaped vessel 32, which, of course, must be a trihedral corner reflector. The reflected acoustical pulse travels path 94 back toward source 26 and a portion travels path 95 toward hydrophone 24 where it is received, converted to an electrical pulse and is displayed as pulse 84'.
As the maneuvering continues to reduce the distance between pulses 54' and 58' the amplitude of pulse 84' will increase. Drill string 22 will be aligned with wellhead 30 when this minimum distance is achieved and the amplitude of pulse 84' is a maximum. The distance between pulses 58' and 84' will remain fixed as drill string 22 is lowered into wellhead 30.
Conclusion From the foregoing it will be apparent that we have disclosed a method and apparatus for accurately and reliably guiding equipment from an ocean platform to a submarine Wellhead and that the same may be readily mastered by the operators of ocean-type drilling rigs.
It will be understood that various changes in the details, materials, steps and arrangements of parts which have been herein described and illustrated in order to explain the nature of the invention may be made by those skilled in the art. For example, trihedral corner reflectors may be made of material having a thickness equal to onequarter of the wavelength of the frequency of the pulsed acoustical source in the material to assure that acoustical energy reflected from top and bottom surfaces of the material is in phase in the reflected acoustical pulse. Accordingly all such changes are considered to fall within the spirit and scope of the invention.
7 We claim: 1. The method of aligning equipment between an ocean platform and a submarine wellhead comprising:
producing first pulses of acoustical energy portions of which radiate toward the wellhead and toward a predetermined point;
producing at the wellhead second pulses of acoustical energy in response to receipt of portions of the first pulses of acoustical energy, portions of which second pulses of acoustical energy radiate toward the predetermined point;
directively reflecting part of the portions of the first pulses of acoustical energy received at the wellhead back from the wellhead toward the predetermined point, as reflected acoustical pulses;
measuring the time difference of arrival at the predetermined point of the portions of the first and second pulses;
receiving the reflected acoustical pulses at the predetermined point; and
maneuvering the ocean platform until the time difference becomes a minimum and the amplitude of the received reflected acoustical pulses becomes a maximum.
2. Apparatus for guiding equipment from an ocean platform to a submarine wellhead comprising a trihedral corner reflector located at the wellhead,
having a large triangular opening with a small opening at its corner aflixed to the top of the wellhead and its axis aligned substantially with the axis of the well;
a hydrophone located at a first predetermined point;
a first pulsed acoustical source located at a second predetermined point for producing first pulses of acoustical energy, portions of which radiate toward and impinge upon the trihedral corner reflector and are directively reflected toward the first predetermined point as reflected acoustical pulses, portions of which are received by the hydrophone, the equipment being located at one of the predetermined points;
a transponder so disposed at the trihedral corner reflector as to radiate second pulses of acoustical energy toward the hydrophone at the first predetermined point in response to receipt of portions of the first pulses of acoustical energy;
means connected to the hydrophone and associated with the source for indicating a time diflerence between the first and second pulses and adapted to display waveforms of the portions of the received reflected acoustical pulses;
means associated with the ocean platform for maneuvering the equipment until the time difference is a minimum and the amplitude of the portions of the received reflected acoustical pulses reaches a maximum; and
means also associated with the ocean platform for lowering the equipment toward the wellhead when the time difference is a minimum and for lowering the equipment into the wellhead when the amplitude of the portions of the received reflected acoustical pulses is a maximum.
3. Apparatus as in claim 2 in which:
the first predetermined point is at the equipment; and
the second predetermined point is at the ocean platform.
References Cited UNITED STATES PATENTS 2,520,520 8/1950 Woodard 340-2 X 3,195,677 7/1965 Hillery et a1 181-.5 3,222,634 12/1965 Foster 340-3 3,293,867 12/1966 Dean. 3,336,572 8/1967 Paull et al 3406 RICHARD A. FARLEY, Primary Examiner
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Cited By (16)

* Cited by examiner, † Cited by third party
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US3599747A (en) * 1968-12-16 1971-08-17 Palle G Hansen Spherical reflector
US3622962A (en) * 1969-09-09 1971-11-23 Us Navy Free fall oceanographic beacon
US3731263A (en) * 1971-04-28 1973-05-01 Eg & G Inc Underwater guidance method and apparatus
US3788396A (en) * 1971-03-10 1974-01-29 Shell Oil Co Well re-entry tool with bumperhead
US4047579A (en) * 1975-09-27 1977-09-13 Rheinstahl Ag Sea drilling jig
US4344721A (en) * 1980-08-04 1982-08-17 Conoco Inc. Multiple anchors for a tension leg platform
US4451177A (en) * 1982-02-08 1984-05-29 Conoco Inc. Guideline system for positioning subsea equipment
US4468155A (en) * 1981-11-24 1984-08-28 Institut Francais Du Petrole Method and device for placing in a determined relative position two elements submerged in a conducting liquid medium
US4547163A (en) * 1980-06-03 1985-10-15 Licentia Patent-Verwaltungs-G.M.B.H. Oil transfer apparatus
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US5652593A (en) * 1994-09-29 1997-07-29 Von Schrader Company Method and apparatus for guiding a machine
US9404347B1 (en) * 2015-05-15 2016-08-02 Baker Hughes Incorporated Apparatus and method for connecting a riser from an offshore rig to a subsea structure
US9719330B2 (en) * 2015-12-28 2017-08-01 Cameron International Corporation Subsea equipment pendulum arrestor and method for its use
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US3599747A (en) * 1968-12-16 1971-08-17 Palle G Hansen Spherical reflector
US3622962A (en) * 1969-09-09 1971-11-23 Us Navy Free fall oceanographic beacon
US3788396A (en) * 1971-03-10 1974-01-29 Shell Oil Co Well re-entry tool with bumperhead
US3731263A (en) * 1971-04-28 1973-05-01 Eg & G Inc Underwater guidance method and apparatus
US4047579A (en) * 1975-09-27 1977-09-13 Rheinstahl Ag Sea drilling jig
US4547163A (en) * 1980-06-03 1985-10-15 Licentia Patent-Verwaltungs-G.M.B.H. Oil transfer apparatus
US4344721A (en) * 1980-08-04 1982-08-17 Conoco Inc. Multiple anchors for a tension leg platform
US4468155A (en) * 1981-11-24 1984-08-28 Institut Francais Du Petrole Method and device for placing in a determined relative position two elements submerged in a conducting liquid medium
US4591293A (en) * 1981-11-24 1986-05-27 Institut Francais Du Petrole Method and device for placing in a determined relative position two elements submerged in a conducting liquid medium
US4451177A (en) * 1982-02-08 1984-05-29 Conoco Inc. Guideline system for positioning subsea equipment
US4673313A (en) * 1985-04-11 1987-06-16 Mobil Oil Corporation Marine production riser and method for installing same
EP0214453A2 (en) * 1985-08-13 1987-03-18 Edelhoff M.S.T.S. Gmbh System for determining the position of an object relative to a manipulating device
EP0214453A3 (en) * 1985-08-13 1988-11-23 Edelhoff Polytechnik Gmbh & Co. System for determining the position of an object relative to a manipulating device
US5418758A (en) * 1991-03-22 1995-05-23 Connell Wagner (Old) Pty. Ltd. Distance measurement system
US5652593A (en) * 1994-09-29 1997-07-29 Von Schrader Company Method and apparatus for guiding a machine
US9404347B1 (en) * 2015-05-15 2016-08-02 Baker Hughes Incorporated Apparatus and method for connecting a riser from an offshore rig to a subsea structure
US9719330B2 (en) * 2015-12-28 2017-08-01 Cameron International Corporation Subsea equipment pendulum arrestor and method for its use
US11401794B2 (en) * 2018-11-13 2022-08-02 Motive Drilling Technologies, Inc. Apparatus and methods for determining information from a well
US20220259967A1 (en) * 2018-11-13 2022-08-18 Motive Drilling Technologies, Inc. Apparatus and methods for determining information from a well
US11988083B2 (en) * 2018-11-13 2024-05-21 Motive Drilling Technologies, Inc. Apparatus and methods for determining information from a well

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