|Publication number||US3760875 A|
|Publication date||Sep 25, 1973|
|Filing date||May 26, 1971|
|Priority date||Jun 29, 1970|
|Also published as||CA936046A, CA936046A1, DE2132060A1, DE2132060B2|
|Publication number||US 3760875 A, US 3760875A, US-A-3760875, US3760875 A, US3760875A|
|Original Assignee||Shell Oil Co|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (5), Referenced by (37), Classifications (24)|
|External Links: USPTO, USPTO Assignment, Espacenet|
United States Patent 1191 Busking Sept. 25, 1973 1 FLOATING STRUCTURE WITH ROTATABLE TEMPLET FOR CONNECTING GUIDE LINES THERETO  Inventor: Bob E. Busking, The Hague,
Netherlands  Assignee: Shell Oil Company, New York, NY.
 Filed: May 26, 1971 1211 Appl. No.: 147,110
 Foreign Application Priority Data June 29, 1970 Great Britain 31,390/70  U.S. C1. 166/.5, 114/.5 D  Int. Cl EZlb 7/12, E21b 43/01  Field of Search 166/.5, .6; 175/7, 175/5; 114/.5 D
 References Cited UNITED STATES PATENTS 3,191,201 6/1965 Richardson et a1 114/.5 D 3,279,404 10/1966 Richardson 114/.5 D
3,481,294 12/1969 Vincent 175/7 3,602,302 8/1971 Kluth 166/.5 3,605,668 9/1971 Morgan 175/7 Primary Examiner-Marvin A. Champion Assistant ExaminerRichard E. Favreau Attorney-Theodore E. Bieber and Harold L. Denkler [5 7 ABSTRACT A constant tension system for guide lines used in connecting an underwater wellhead to a dynamically stationed ship wherein twisting of the guidelines is prevented by mounting the guidelines on a rotatable templete disposed on the structure.
3 Claims, 1 Drawing Figure 4. r" 'CONTROL 1 2 76 TRANSDUCER I6 TRANSDUCER Pmmmsm 3,760,875
42 CONTROL BEBusk/ng,
INVENTOR FLOATING sTRucTunEwrrn ROTATABLE TEMPLET FOR' CONNECTING eunm LINES THERETO 1 BACKGROUND OF THE INVENTION The invention relates to a floating structure which is suitable for carrying out well drilling, completion, workover and/or production operations. Since the structure has to remain above the location where these operations are carried out, means are provided for maintaining the structure, such as a ship or a floating platform, at such location during the period that these operations are carried out. I
In particular, thepresent invention relates to a floating structure provided with a dynamic stationing sysmm, which canbe applied with special advantage in deep waters where anchoring by means of anchors and anchor cables is not possible or attractive. Sucha dynamicstationingsystem comprises measuring means for measuring the displacement of the floating platform from a desired location, and means for controlling propulsion units of the structure in such a manner that this displacement is kept as small as possible. Such a system .may, if desirable, further include measuring means for measuring the deviation of the floating platform from a desired heading, and means for controlling propulsion units of the structure in such a manner as to keep this deviation as small as possible. It will be understood that in such a system the forces for stationing the floating structure are solely provided by the propulsion units of the floating structure, which units may include bow and/or stern propellers and/or propellers of the Voith Schneider type (also referred to as vertical blade "In a preferred method of operation, the desired heading corresponds to the direction from which the wind is blowing, and the floating structure is, notwithstanding the wave, wind and current forces acting on the structure, kept at the desired location in the desired heading by the dynamic stationing system. It will be appreciated that a change in wind direction calls for a resetting of the desired heading, since, in particular when the floating structure is a ship, such a change may result in an increase of the forces exerted by the wind on the ship. However, if the forces exerted on the structure by the water current are dominant, the desired heading will be set in relation to the prevailing water current.
A floating structure as mentioned hereinabove for carrying out well drilling, completion, workover and/or A drawback attached to the use of these lines or cables extending between the floating structure provided with a dynamic stationing system and submerged well equipment is that the lines or cables are liable to become twisted and damaged owing to contactwith the marine riser pipe by the movements of the structure, or the re-setting of the desired heading.
BRIEF SUMMARY OF THE INVENTION The object of the present invention is to prevent such twisting and-damage of cables and/or lines extending between underwater well equipment and a floating structure which is provided with a dynamic stationing system.
According to the invention,a floating structure provided with a dynamic stationing system comprises a moonpool extending substantially vertically through the structure and suitable for passing equipment therethrough when carrying out well drilling, completion, workover and/or production operations, a derrick mounted on the structure at a location above the moonpool, a templet mounted around the moonpool, which templetis rotatable with respect to the floating structure and the derrick mounted thereon, and at least one constant tension device mounted on the' templet, an elongated flexible means being coupled at one end thereof to the constant tension device, the other end of said means being suitable for connection to underwater well equipment.
The elongated flexible means may be a guide line or a hose cable.
Means may be provided for rotating the rotatable templet.
BRIEF DESCRIPTION OF THE DRAWINGS DESCRIPTION OF PREFERRED EMBODIMENT The ship 1 floating in the sea'2 comprises a well or moonpool 3 extending vertically through the body of the ship and suitable for'passing drilling equipment as well as completion equipment therethrough. Above the moonpool 3 a derrick 4 is mounted on the drilling floor 5, which in its turn is mounted on the deck 6 of the ship 1 by means of columns 7. With the exception of the rotary table 8, all the other equipment as used on the drilling floor 5 and in the derrick 4 is not shown for sake of simplicity.
The templet 9 is mounted above the moonpool 3 and below the drilling floor 5, in a rotatable manner around the central axis of the moonpool 3 by means of the bearing elements 10.
The ship 1 is kept at the desired location above the well 11 penetrating the sea bottom 12, by propulsion means of'which only one, being a Voith Schneider propeller l3 installed forward of the moonpool is shown. Acoustic transmitters 14 (of which only two are shown) are mounted on the base member 15 of the well 11, and the acoustic signals generated by the transmitters are received by the listening microphones 16 carried by the ship 1 (only two microphones being shown in the drawing). The signals received by the micro- 4 phones are sent to a measuring and control device 17,
in which the displacement from the desired location is measured and control signals are generated for controlling the operation of the Voith Schneider propeller 13 as well as the operation of any other propulsion unit (not shown) which is used for stationing the ship 1. The control signals generated may include information obtained on the deviation of the ship from a desired heading. To this end, a compass 18 is provided suitable for determining the magnitude of this deviation, which is then supplied to the measuring and control device 17 and combined with the information on the displacement for generating control signals to be supplied to the propulsion units acting to keep the ship on the desired location and on the desired heading.
In the dynamic stationing system as shown in the drawing, the transmitters l4 operate on different frequencies and the time intervals between the moments of arrival of the signals of a common frequency at the receivers 16 are used for calculating the displacement of the ship from the desired location.
It will be appreciated that the dynamic stationing system as schematically shown in the drawing is only indicated by way of example. There are various other types of dynamic stationing systems which are known per se and which may be used in a floating structure according to the present invention.
The base member of the well 11 further carries guide posts 19 to. which are connected guide lines 20 running upwards to the ship 1. The lines are connected to the drums 21 of constant tension winches 22 which are mounted on the rotatable templet 9. The guide lines 20 are used for guiding well equipment from the ship 1 to the well 11, such as the wellhead 23 which is provided with guide bars 24 co-operating with the guide lines 20, and the marine conductor 25 provided with guide bars 26 near the lower end thereof. The guide bars are in contact with the guide posts 19 over the lower part of their track along the guide lines 20, thus exactly centering the well equipment on the entrance to the well 11.
The upper part of the marine conductor 25 includes a telescopic section 27 of which the upper part is carried by the drilling floor 5, the section 27 allowing the length of the conductor 25 to be adapted to the variations in distance between the drilling table 8 and the sea bottom 28 resulting from the wave action.
At a level below the telescopic section 27, a rotatable bearingelement 29 is arranged around the marine conductor 25. One side of the bearing element is connected to the conductor 25. The other side of the bearing element is supported by supporting cables 30. Each cable 30 is connected at the other end thereof to a constant tension device 31 and guided thereto via a sheave 32. The constant tension devices are each connected to a column 7. Each device 31 comprises a high pressure pneumatic cylinder 33 mounted on the column 7, the cylinder having a piston with piston rod 34 slidably arranged therein. Means (not shown) are provided for maintaining a constant pressure within the cylinder space below the piston. Each cable is guided over two sheave blocks, one block 35 being mounted at the closed end of the cylinder 33, the other block 36 being mounted on the free end of the piston rod 34. The end of each cable 30 is connected to a point fixed with respect to the cylinder 33.
OPERATION OF PREFERRED EMBODIMENT The ship 1 is dynamically stationed on a desired heading and on a location vertically above the well 1 l, and the cables 20 are arranged to form a guide for any equipment which is to be displaced between the ship 1 and the well 11 and vice versa. The winches 22 are actuated to keep the tension in these cables 20 substantially constant notwithstanding variations in distance between the ship 1 and the sea bottom 28 due to wave action. The same applies to the constant tension devices 31 which by means of the supporting cables 30 maintain a substantially constant tension in the upper part of the marine conductor 25 independent of wave action.
When the desired heading of the ship 1 has been reset (e.g., after shifting of the wind), the dynamic stationing system will keep the heading of the ship as close as possible to this new heading, which means that the ship will be rotated with respect to the well over an angle corresponding -to the deviation between the old heading and the new heading. To prevent twisting of the guide cables 20 and to prevent them from touching the marine riser pipe 25, the templet 9 together with the constant tension devices 22 carried thereby is rotated through an angle equal to the deviation between the two headings. Thus the cables 20 remain parallel to each other and to the marine conductor 25 and-will not be twisted.
Since the supporting cables 30 are suspended from the sheaves 32 which are mounted to the drilling floor 5, these cables will be displaced through an angle equal to the deviation between the old heading and the new heading after re-setting the desired heading. As, however, the lower ends of these cables are connected to a part of the supporting element 29 which is rotatably arranged with respect to the conductor 25, the cables 30 will remain in a common plane but move to a plane. different from the plane in which they were originally positioned. The guide cables 20, however, always remain in the same plane.
It will be understood that the templet 9 is preferably rotated by means of an electric motor 40 driving the templet through a gear arrangement 41. The templet may also be rotated by hydraulic means which may actuate the templet by means of a pinion co-operating with gear teeth arranged around the circumference of the circular templet.
The operation of the electric motor or the hydraulic system may be controlled by a push button. However, a control system 42 may be applied for controlling the operation of the electric motor automatically such that the templet is kept in a desired position under all circumstances. This arrangement is particularly preferred when applying a dynamic positioning system which controls only the displacement of the ship from a desired location, and not the deviation of the ship from a desired heading.
It will be understood that the invention is not restricted to the particular embodiment as shown in the drawing by way of example. Thus, the constant tension devices 22 as used for maintaining a substantially constant tension on the guide cables 20 need not be winches, but may be of any other type suitable for the purpose, such as the type 31 as applied for tensioning the cables 30. However, these constant tension devices 22 will always be mounted on the templet 9.
Since the lateral loads exerted on the templet by the guide cables 20 are of onlysmall magnitude, no special measures have to be taken to support the templet 9 against lateral loading. The bearing elements 10 may be of any type suitable for the purpose.
The number of guide cables may be more than two (as shown in the drawing) or even one. Further, any other connection between the ship 1 and the well 11 and formed by an elongated flexible means, such as a hose cable, may be protected against twisting with respect to other cables or to the marine conductor in the manner as described with reference to the cables 20. The hose cable as mentioned may be applied for communication purposes by passing hydraulic signals therethrough from the ship 1 to the equipment on the well 11.
Although the derrick 4 as applied is mounted in a fixed position on the deck 6 of the ship during drilling, completion or workover operations, this derrick may be displaced with respect to the moonpool 3 between such operations.
I claim as my invention:
1. An improvement in a floating structure provided with a dynamic stationing system, including a moonpool extending substantially vertically through the structure and suitable for passing equipment therethrough when carrying out well drilling, completion, workover and/or production operations, a derrick mounted on the structure at a location above the moonpool, and underwater wellhead equipment disposed on the floor of the body of water, said improvement comprising:
a templet mounted around the moonpool, said templet being rotatable with respect to the floating structure and the derrick mounted thereon, at least one constant tension device mounted on the templet, and 1 an elongated flexible hose cable being coupled at one end thereof to the constant tension device, the other end of the hose cable being suitable for connection to the underwater well equipment.
2. A floating structure according to claim 1, and in addition a marine conductor extending from the floating structure to the wellhead, a supporting cable which is connected at one end thereof to a rotatable bearing element suitable for being connected to said marine conductor, and connected at the other end to a constant tension device which is mounted on a part of the structure which is stationary with respect to the templet.
3. A floating structure according to claim 1 and in addition drive means for rotating the rotatable templet, measuring means for measuring the deviation of the structure with respect to a predetermined heading and for controlling the drive means for so rotating the rotatable templet that the deviation of the templet with respect to the predetermined heading is as small as possible.
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|U.S. Classification||166/354, 166/359, 114/264, 114/268, 166/355|
|International Classification||E21B41/00, E21B41/10, E21B15/02, E21B19/00, E21B15/00, E21B19/09, G05D1/02, E21B7/128, E21B7/12|
|Cooperative Classification||E21B15/02, E21B19/09, E21B41/10, G05D1/0208, E21B7/128|
|European Classification||E21B15/02, G05D1/02C4, E21B19/09, E21B7/128, E21B41/10|