GB1586425A – Position determining and dynamic positioning method and system for floating marine well drilling platforms and the like
– Google Patents
GB1586425A – Position determining and dynamic positioning method and system for floating marine well drilling platforms and the like
– Google Patents
Position determining and dynamic positioning method and system for floating marine well drilling platforms and the like
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Publication number
GB1586425A
GB1586425A
GB19617/78A
GB1961778A
GB1586425A
GB 1586425 A
GB1586425 A
GB 1586425A
GB 19617/78 A
GB19617/78 A
GB 19617/78A
GB 1961778 A
GB1961778 A
GB 1961778A
GB 1586425 A
GB1586425 A
GB 1586425A
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GB
United Kingdom
Prior art keywords
platform
connecting line
angle
signal
signals
Prior art date
1977-05-16
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired
Application number
GB19617/78A
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Northrop Grumman Space and Mission Systems Corp
Original Assignee
TRW Inc
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
1977-05-16
Filing date
1978-05-15
Publication date
1981-03-18
1978-05-15
Application filed by TRW Inc
filed
Critical
TRW Inc
1981-03-18
Publication of GB1586425A
publication
Critical
patent/GB1586425A/en
Status
Expired
legal-status
Critical
Current
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Classifications
G—PHYSICS
G05—CONTROLLING; REGULATING
G05D—SYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
G05D1/00—Control of position, course or altitude of land, water, air, or space vehicles, e.g. automatic pilot
G05D1/02—Control of position or course in two dimensions
G05D1/0206—Control of position or course in two dimensions specially adapted to water vehicles
G05D1/0208—Control of position or course in two dimensions specially adapted to water vehicles dynamic anchoring
F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
F02B—INTERNAL-COMBUSTION PISTON ENGINES; COMBUSTION ENGINES IN GENERAL
F02B75/00—Other engines
F02B75/02—Engines characterised by their cycles, e.g. six-stroke
F02B2075/022—Engines characterised by their cycles, e.g. six-stroke having less than six strokes per cycle
F02B2075/027—Engines characterised by their cycles, e.g. six-stroke having less than six strokes per cycle four
Description
(54) POSITION DETERMINING AND DYNAMIC
POSITIONING METHOD AND SYSTEM FOR
FLOATING MARINE WELL DRILLING
PLATFORMS AND THE LIKE
(71) TRW INC., a corporation organized and existing under the laws of the
State of Ohio, United States of America, of One Space Park, Redondo Beach,
California, United States of America, do hereby declare the invention for which we pray that a patent may be granted to us, and the method by which it is to be performed to be particularly described in and by the following statement:- The present invention relates to a method and system for determining the relative horizontal positions of upper and lower ends of a connecting line suspended from a marine platform and to a method and system for positioning a platform relative to a reference position on the ocean floor.
The ever increasing rate of petroleum consumption coupled with the current price demands of the primary oil producing countries has created the necessity of offshore oil and gas well drilling and producing operations in water of ever increasing depth and a resulting marine platform positioning or station keeping problem of ever increasing complexity and difficulty. In this latter regard, it is known that offshore oil and gas well drilling and producing operations in relatively shallow water, up to a depth of 2000 feet, for example, may be performed from a fixed tower-like structure which rests directly on and is firmly anchored directly to the ocean floor. At greater depths, floating platforms’must be employed for such operations. These platforms must somehow be retained in a relatively fixed position over the well bore being drilled into or the well head on the ocean floor.
A floating oil well drilling installation, for example, has a floating drilling platform and a drill string extending from the platform to the ocean floor which is driven in rotation from the platform to drill a well bore into the floor. A floating oil or gas producing installation has a riser extending from the floating platform to the well head on the ocean floor and pumping means on the platform for pumping oil upwardly through the riser. The drill string and casing or riser, as the case may be, is thus fixed at its lower end, while its upper end moves horizontally and vertically with the floating platform. Floating at the water surface as it does, the platform is subject to displacement from its optimum position over the well bore or well head by wind, wave, and/or ocean current action.Accordingly, platform positioning or station keeping means must be provided for retaining the platform in position against the action of such forces.
Two general types of platform positioning techniques, one passive and the other dynamic, have been devised for this purpose. The passive platform positioning technique involves simply anchoring or tethering the platform in a fixed position with cables extending from the platform to anchors fixed to the ocean floor. The dynamic platform positioning technique involves sensing departure of the floating platform from its optimum position and continuously driving the platform back toward such position. The present invention is concerned with a dynamic platform positioning technique.
A wide variety of dynamic platform positioning techniques have been devised.
A few of these are described in the following patents:
3,121,954 3,508,512
3,148,653 3,588,796
3,187,704 3,730,126 3,191,570 3,886,887
3,311,079 3,948,201
3,369,516
The dynamic platform positioning techniques described in many of these patents involve sensing and generating signals representing, in terms of a selected coordinate system the angle of a connecting line extending from the platform to a fixed reference position on the ocean floor, and controlling a platform propulsion system in response to these signals in such a way as to maintain the platform in a desired horizontal position relative to the reference. The connecting line is a cable in patent No. 3,187,704, and a casing or drill string in patent No. 3,191,570. Patent
No. 3,148,653 shows two connecting lines, one a cable and one a drill string.
The prior art dynamic floating platform positioning systems which utilize such a connecting line suffer from two major deficiencies which this invention overcomes. The first deficiency resides in the fact that these platform positioning systems assume the connecting line to be essentially linear along its full length from the floating platform to the ocean and rely on an angle measurement of one end only of the connecting line. In some cases, this angle measurement is made at the floating platform as in patent No. 3,121,954 and in other cases, at the ocean floor as in patent No. 3,191,570. Patent No. 3,148,653, which employs two separate connecting lines,.i.e., a cable and a drill string, makes the cable angle measurement at the platform and the drill string angle measurement at the ocean floor.
In actual practice, however, the connecting line becomes increasingly more nonlinear and its nonlinearity becomes more time variable as the water depth increases due to several factors, such as surface wave induced platform motion which produces travelling stress waves or undulations in the connecting line, ocean currents, the weight of the connecting line itself, changing connecting line tension and the like.
The second deficiency is related to the phase lag which exists between true platform position and sensor measured platform position, particularly at depths exceeding approximately 2500 feet, when the bottom angle of the connecting line is used for position determination. This phase lag is due to the transit time required for platform motion induced stress waves or undulations to propagate downwardly through the connecting line to the botton angle sensor. When a position measuring system which introduces such phase lag is incorporated into a closed loop dynamic positioning system, the stability of the closed loop system is degraded, and in some instances, may become completely unstable.
As a consequence of the foregoing and other deficiencies, the existing dynamic floating platform position systems of the character described are useful only in relatively shallow water up to depths in the order of 2500 feet. On the other hand, present and near future offshore oil operations contemplate accurate marine platform positioning in water up to depths of 6000 feet and more. Accordingly, there is a need for an improved dynamic marine platform positioning or station keeping system.
According to one aspect, this invention provides a system for determining the relative horizontal positions of the upper and lower ends of a flexible connecting line suspended from a floating marine platform, and wherein the length of said line is many orders of magnitude greater than the relative horizontal displacement of the connecting line ends, said system comprising: angle sensing means including upper and lower connecting line angle sensors for producing angle signals representing the vertical slope angles and azimuth angles of the upper and lower ends of said connecting line, and signal processing means for combining said angle signals in accordance with a predetermined relationship of said slope angles which compensates for phase difference between the sensor outputs due to the propagation time of stress waves through said line to provide an output signal representing said relative horizontal positions.
According to another aspect, this invention provides a method of determining the relative horizontal positions of the upper and lower ends of a flexible connecting line suspended from a floating marine platform, and wherein the length of said line is many orders of magnitude greater than the relative horizontal displacement of the connecting line ends, said system comprising: sensing and producing angle signals representing the vertical slope angles and azimuth angles of the upper and lower ends of said connecting line, and combining said angle signals in accordance with a predetermined relationship of said slope angles which compensates for phase difference between the sensor outputs due to the propagation time of stress waves through said line to provide output signals means representing said relative horizontal positions.
The suspended line may be a cable for anchoring the platform to the ocean floor, a drill string for drilling a well bore into the ocean floor or a riser for attachment to an ocean floor well head.
Another aspect of the invention is concerned with a system of positioning a floating marine platform relative to a reference position on the ocean floor comprising: a flexible connecting line extending between said platform and reference position, angle sensing means including upper and lower connecting line angle sensors for sensing and producing angle signals representing the vertical slope angle and azimuth angles of the upper and lower ends of said connecting line, signal processing means for combining said signals in accordance with a
predetermined relationship and producing an output signal representing the
horizontal position of said platform to said reference position, and means for
horizontally positioning said platform in response td said signal.
From yet another aspect, the present invention provides a method of positioning a floating marine platform relative to a reference position on the ocean floor comprising: sensing and producing angle signal representing the vertical slope angles and azimuth angles of the upper and lower ends of a flexible
connecting line extending between said platform and reference position,
combining said signals in accordance with a predetermined relationship and producing an output signal representing the horizontal position of said platform
relative to said reference position, and horizontally positioning said platform in
response to said signal.
The preferred embodiment of the invention is particularly adapted for use in
relatively deep water, of the order of 6000 feet or more, for example, where
surfaces wave induced motion of the floating platform and other fluctuating forces
produce travelling undulations in the connecting line.
The present position determining system involves sensing and producing angle
signals containing information representing the vertical slope angles of the
submerged connecting line at or near its upper and lower ends and, if necessary for
position determination, also azimuth information defining the azimuthal angle or
direction of the connecting line relative to a selected azimuth reference. These
angle signals are filtered to eliminate higher order frequency components produced
by surface wave induced connecting line undulations and the like, whereby the filtered angle signals represent, in effect, the mean vertical slope angles of the connecting line ends, i.e., the upper and lower vertical slope angles of the envelope
of the undulating connecting line.The filtered signals are combined in
predetermined relationship with signals representing selected connecting line,
platform, and marine parameters, referred to collectively as basic system parameters, to produce an output representing the relative horizontal positions of
the upper and lower connecting line ends. Assuming the connecting line is
anchored to the ocean floor, this output represents the horizontal position of the
platform relative to the ocean floor anchor point of the connecting line.
The present platform positioning or station keeping invention embodies the
position determining system arid a platform propulsion system for maintaining a floating platform in a predetermined horizontal position relative to a selected
ocean floor reference point. According to this aspect of the invention, the
connecting line is anchored to the ocean floor, and the output from the position
determining system is utilized to control the platform propulsion system in such a
way as to maintain the platform in the desired position.
In some applications, the basic system parameters may remain sufficiently
constant during any given operating period to enable the same parameter values to
be used during the entire operating period. In other applications, at least some of
these parameters may be subject to change. It is contemplated that such
changeable parameters be sensed and their values updated as required.
In order that the present invention be more readily understood an embodiment thereof will now be described by way of example with reference to the
accompanying drawings, in which: Figure 1 diagrammatically illustrates a marine platform positioning system
according to the invention;
Figure 2 is a schematic circuit diagram of the system;
Figure 3 diagrammatically illustrates the algorithm utilized in the invention;
Figures 4 and 5 are diagrams illustrating certain relationships involved in the
derivation of a position equation for use in the invention; and
Figure 6 is a view similar to Figure 1 showing the use of a riser as the connecting line.
Turning first to Figure 1, reference numeral 10 denotes a marine platform floating at the surface of a body of water 12, such as the ocean, and required to be maintained in a predetermined horizontal position relative to a reference P on the ocean floor 14. Platform 10 is equipped with a position determining system 16 according to this invention for producing a position signal representing the horizontal position of the platform relative to the ocean floor reference P and with a dynamic platform positioning or station keeping system 18 controlled by this position signal for maintaining the floating platform 10 in the desired position relative to the ocean floor reference.
In general terms, the floating platform position determining system comprises a flexible connecting line 20 extending from the floating platform 10 to the ocean floor 14, means 22 for sensing and regulating the tension in this connecting line, means 24 for sensing and producing angle signals representing in terms of a selected coordinate system, the vertical slope and horizontal azimuth angles of the connecting line 20 at or near its upper and lower ends, and in some cases also the rates of change of these angles, and signal processing means 25 for combining these angle signals in accordance with a position equation relating the connecting line angles and selected system parameters, including connecting line, platform, and ocean parameters, to provide a position signal output representing the horizontal position of the marine structure 10 relative to the ocean floor reference P.This equation corrects or compensates for phase lag between true platform position and sensor measured platform position due to the propagation time of platform motion induced stresses along the connecting line. Signal processing means 25 filters the angle signals from the connecting line angle sensors to remove higher order signal frequencies resulting from surface wave induced undulations in the connecting line.
The system operation occurs in a manner such that the platform position determination is based on a relatively close approximation of the mean nonlinear path or envelope of the connecting line 20. As a consequence, the position determining system 16 provides an output which represents, with a relatively high degree of accuracy even in relatively deep water of the order of 6000 feet or more, the horizontal position of the platform relative to the ocean floor reference.
As mentioned earlier, and will become readily evident as the description proceeds, the connecting line 20 may be a cable, an oil well drill string, a casing string or riser or the like. In the following description, it will be assumed that the lower end of the connecting line 20 is anchored to the ocean floor 14 at the ocean floor reference P. It should be understood, however, that the concepts and implementation of the present invention are equally applicable to determining the relative position of the upper and lower ends of a line or riser which is not attached to the sea floor.
As noted earlier, it is the practice of the invention to measure and use in the computation of the horizontal position of the platform 10, the vertical slope angles at or near both ends of the connecting line 20. To this end, the angle signal producing means 24 includes angle sensing means 26, 28 at or near both the lower and upper ends respectively of the connecting line.
It will be recognized that the horizontal position of the platform 10 relative to ocean floor reference P may be measured and expressed in terms of any suitable coordinate system. In this disclosure, the platform position is measured and expressed in terms of a Cartesian coordinate system whose Z axis is vertical and passes through the reference P and whose X and Y axes are horizontal in the east/west and north/south directions, respectively. The lower connecting line end angle sensing means 26 produces an output representative of the vertical slope angle of a tangent to the lower connecting line end, measured in the X-Z plane, and in the Y-Z plane, respectively.These two slope angles obviously define both the true vertical slope of the lower connecting line, that is, the angle between the Z axis and a tangent to the lower portion of the connecting line measured in the plane containing the latter axis and tangent, and the azimuth angle of the lower end, that is, the angle between the latter plane and a selected datum plane, such as the X-Z plane. The upper angle sensing means 28 produces an output representing the vertical slope angle of a tangent to the upper end of the connecting line measured in two vertical, mutually perpendicular planes of the platform 10 parallel to the X
Z and Y-Z planes, respectively. These slope angles define both the true vertical slope angle and azimuth angle of the upper connecting line end. As will be explained later, in some applications, the angle sensing means 26, 28 may also sense and produce signals representing the rates of change of the connecting line slope angles.
At this point, it is significant to recall from the earlier discussion that the existing dynamic floating platform positioning systems of the general class to which this invention pertains are deficient for the reason that they ignore phase lag in the systems and assume the connecting line 20 to be linear from the floating platform 10 to the ocean floor 14. In actuality, however, a significant phase lag exists between the lower angle sensor output and the actual platform position. This phase lag increases with water depth and results from the transit time required for stress waves or lateral deformations produced in the upper end of the connecting line by wave induced and other movements of the platform to propagate downwardly through the connecting line to and be reflected in a corresponding change in the slope/azimuth angle output of the lower connecting line angle sensor 26.Also, the connecting line deviates substantially from a linear condition due both to relatively static forces, such as gravitational and ocean current forces which tend to cause the connecting line to become curved and to dynamic forces such as wave induced motion of the floating platform which cause traveling deformations or undulations in the connecting line. Such system phase lag and connecting line nonlinearity increase with the water depth and are dependent on various other factors, such as the physical characteristics, i.e., stiffness, weight per unit length, etc., of the connecting line, the tension in the line and the characteristics of the floating platform.Since such phase lag and connecting line nonlinearity increase with depth and are not taken into account in or factored into the platform position determination made by the existing dynamic platform positioning systems, these existing systems are limited in use to the relatively shallow water depths mentioned earlier.
In contrast, in the present invention, system phase lag and connecting line nonlinearity are corrected for or factored into the platform position determination in a manner which yields a relatively accurate determination or measurement of the position of platform 10 relative to the ocean floor reference P, even in water depths of the order of 6000 feet or more. To this end, the platform position determination is based on a platform position equation which may be stated in simple terms as follows:
A,B=f(a,b,a’,b’,K) ( I ) where:
A,B are coordinates representing the horizontal position of the platform
relative to the datum position, in terms of a selected coordinate system.
a,b,a’,b’ are the vertical slope and horizontal azimuth angles, respectively, in
terms of the selected coordinate system, of the connecting line 20 at or
near its upper and lower ends, respectively,
K are selected position determining system parameters such as connecting line
tension, weight per unit length, moment of inertia, and stiffness or
modulus of elasticity, water depth, ocean current direction and
magnitude, sea spectrum, etc., and
f is a functional relationship of the quantities a,b,a’,b’ and K which effectively
provides platform position coordinate values A,B based on a relatively
close approximation of the system phase lag and true curvature of the
connecting line.
The invention contemplates within its scope any functional relationship f of the quantities a,b,a’,b’, K which will yield a platform position determination
The invention contemplates within its scope any functional relationship f of the quantities a,b,a’,b’,K which will yield a platform position determination or measurement of sufficient accuracy for the particular application at hand and utilization of any suitable coordinate system as a frame of reference for the position determination. The platform position equations (2), (3) set forth below define a presently preferred relationship f for use in practicing the invention. This relationship, i.e., the platform position equations, are based on the Cartesian coordinate system depicted in Figures 4 and 5.
The manner in which the platform position equations (2) and (3) are derived will be explained in detail presently by reference to Figures 4 and 5. Suffice it to say at this point that the Cartesian coordinate system is represented in Figures 4 and 5 by the illustrated X, Y, Z axes whose origin is located at the ocean floor reference point P. The X and Y axes of this coordinate system are horizontal and aligned in selected directions, such as east/west and north/south directions, respectively. The
Z axis is vertical and passes through the reference point.
The platform position equations are as follows: X=Kl(ax)Top+Kz(ex)BOTTOM (2) Y=K1(αy)TOP+K2(αy)BOTTOM (3)
where:
X, Y are the X and Y coordinates of the platform 10 in terms of the Cartesian
coordinate system shdwn in Figures 4 and 5, (αx)TOP, (α;y)TOP are the vertical slope angles at or near the upper end of
connecting line 20 measured in the X-Z and Y-Z planes, respectively, (a,),,,,,, Y)BOTTOM are the vertical slope angles at or near the lower
connecting line end measured in the X-Z and Y-Z plane, respectively,
and K1, K2 are averaging or gain factors which may be complex functions of
frequency and/or include, collectively, a number of system parameters.
As explained in detail presently, the gain factors K1, K2 may be determined
analytically or empirically and are selected to correct or compensate for the earlier
mentioned phase lag in the position determining system, particularly in relatively
deep water. Also, the angle signals from the sensors 26, 28, which represent the
instantaneous values of the cable angles (ax)op, y)TOPs ((tx)BOTTOMs Y)BOTTOMs are
filtered in the manner explained later to eliminate the higher frequency
components produced by surface wave induced undulations in the cable 20.These
filtered angle signals represent the mean vertical slope angles of the cable, or,
stated another way, the vertical slope angles of the cable envelope, and are
combined in accordance with the position equations (2), (3) to obtain the platform
position.
The particular platform position determining system 16 illustrated in Figures
1-5 will now be described in detail. In this illustrated position determining system,
the connecting line 20 is a cable which extends from the floating platform 10 to a
base 30 firmly fixed to the ocean floor 14. The lower end of the cable is firmly
anchored to this base in the manner explained below. The upper end of the cable is
connected to the tensioning means 22 which is carried on the platform 10 and
operates to maintain a relatively constant tension in the cable.
A variety of cable tensioning mechanisms suitable for use in this invention are
available. Accordingly, it is unnecessary to illustrate and describe the tensioning
means in detail. For this reason, the tensioning means is shown in simple
diagrammatic fashion to comprise a take-up drum 32 on which the upper end of
cable 20 is wound and a cable tension sensing means 34 including a tension
responsive roller 35 over which the cable passes to the drum. The take-up drum is
motor-driven under the control of sensing means 34 and in response to the cable
tension in such a way as to maintain a relatively constant predetermined tension in
the cable.
The lower cable angle sensing means 26 comprises a pendulum-type two axis
tilt sensor 36 which measures and produces output signals representing the vertical
slope angle of the lower end of cable 20 in two fixed mutually perpendicular planes
of the cable base 30 and a heading reference source 38 in the cable base 30 for
measuring and producing a signal representing the horizontal heading of the base
relative to the earth. It will be understood, therefore, that the output signals from
the lower cable angle sensing means 26, i.e., tilt sensor 36 and reference source 38,
provide the necessary information for computing the lower cable slope angles (ax)s9uo, (αy)BOTTOM in the earlier stated platform position equations (2), (3).It is
considered to be within the scope of the invention to initially install the base 30 on
the ocean floor 14 with the slope measurement planes of the tilt sensor 36 precisely
aligned with the X-Z and Y-Z planes of the coordinate system. In this case, the
tilt sensor 36 will measure the lower cable slope angles (x)BonoM, (y)BOTTOM directly,
and the base reference source 38 may be eliminated, or at least not used for slope
angle computation.
The tilt sensors in some applications may also produce output signals
representing the rates of change of the cable end angles for use in the platform
position computation performed by the position determining system 16. Two-axis
accelerometers or tilt sensors suitable for use in the platform position determining
system 16 are available from a number of market sources including the Schaevitz
Co., Delco Corporation, Minneapoliz Honeywell Co., and Litton Industries.
As noted earlier, the floating platform position determining system 16 embodies a signal processing means 25. This signal processing means receives the instantaneous cable angle signals from the cable end angle sensing means 26, 28, filters these signals to remove the higher order frequency components produced by wave induced undulations in the cable, and combines the filtered angle signals in accordance with the platform position equations (2), (3) to produce a platform position signal output representing the horizontal position of the marine platform 10 relative to the ocean floor reference P in terms of the Cartesian coordinate system employed. Signal processing means 25 comprises a computer 44 for performing the actual mathematical computations involved in the position equations (2), (3).The filtered angle signals from the angle sensing means 26, 28 are input to this computer along with cable, platform and ocean parameter data which is entered via an operator keyboard 46. The computer 44 outputs to a readout device 48 which may display the coordinates of the platform 10 and/or the input data from keyboard 46. Computer 44 also outputs to the platform positioning system 18 which operates to maintain the platform in a selected horizontal position relative to the ocean floor datum position P.
The lower cable end angle information from the lower cable end angle sensing means 26 is transmitted to the computer 44, which is located on the platform 10, through a signal transmission path 50 in the cable 20. It will be recognized by those versed in the art that a variety of signal transmission techniques may be employed to transmit the lower cable end angle information to the surface through the transmission path 50. The particular marine platform position determining system illustrated utilizes a frequency shift keying (FSK) signal transmission system 52 for this purpose.
FSK system 52 is conventional and comprises an analog multiplexer 54 to which are input the cable end angle and rate signals from the lower cable end twoaxis tilt sensor 36 and the cable base heading signal from the lower cable base reference source 38. Multiplexer 54 outputs to an uplink FSK modulator and cable driver 56 through an analog to digital (A/D) converter 58. The timing and control function of the FSK system 52 is provided by a timing and control logic unit 60.
Electrical power is provided to the lower cable end angle sensing means 26 and to the FSK system 52 from a power source 62 on the platform 10 through an electrical power transmission path 64 in the cable 20. This power source energizes a D.C.
power supply 66 embodied in the FSK system 52 which supplies operating power to the latter system and a calibration voltage to the analog multiplexer 54. It will be understood, therefore, that the FSK system 52 converts the cable angle signals (including angle rate signals, if any) from the lower two-axis tilt sensor 36 and the cable base heading signal from the reference source 38 to multiplexed, digital FSK modulated signals containing lower cable end angle information, cable base heading information, and multiplex timing information.
The digital, multiplexed, FSK modulated signals from the FSK system 52 are transmitted as uplink signals through the uplink cable signal transmission path 50 to circuitry 68 on the floating platform 10. Input circuitry 68 includes an FSK demodulator 70 which receives and demodulates these uplink signals and outputs their contained-digital signal information, i.e., lower cable end angle, cable base heading, and multiplex timing information to a timing extraction and data conditioning circuit 72.This timing extraction and data conditioning circuit also receives the cable end angle signals (including angle rate signals if any) from the upper cable two-axis tilt sensor 40 and the floating platform heading signal from the platform reference source 42 through an A/D converter 74 and a signal transmission path 76 and outputs timing information to the A/D converter 74 through a timing signal transmission path 78. Timing extraction and data conditioning circuit 72 comprises conventional signal conditioning circuitry which conditions its several input signals for proper operation in the computer 44. The conditioned upper and lower cable end angle signals and conditioned cable base and floating platform heading signals from conditioning circuit 72 are input to the computer 44 via a signal transmission path 80.Circuit 72 also inputs to the computer 44, via a signal transmission path 82, a data ready signal in response to receipt of signal information from the bottom and top cable angle sensors 36, 40 and the cable base and platform reference sources 38, 42. The operator keyboard 46 inputs to the computer 44 through a signal transmission path 84.
Referring to Figure 3, the computer 44 has three data input channels 86, 88, 90. Channel 86 is a system parameter input channel including a gain factor determination means 92 which will be explained presently. Suffice to say at this point that this gain factor determination means receives from the keyboard 46 through the signal path 84 system parameter data from which may be determined the gain factors Kl, K2 in the earlier mentioned platform position equations (2), (3).
The gain factor determination means processes this parameter data and outputs to the computer input channels 88, 90 signals representing gain factors K1, K2, respectively, corresponding to the input parameter data from the keyboard 46.
Computer input channels 88, 90 are bottom and top cable angle input channels, respectively. Each channel 88, 90 includes an initial cable angle computation circuit 94, a following multiplier circuit 96, and a final low pass filter circuit 98. The lower cable angle input channel 88 receives from the data conditioning circuit 72 via the signal transmission path 80 conditioned cable angle signals containing information representing the two mutually perpendicular cable angles measured by the top cable slope angle sensor 40 and the heading of the marine platform 10 measured by the platform reference source 42.
It will now be understood that the cable angle input channels 88, 90 of computer 44 receive information from which may be computed the vertical cable slope angles (αx)BOTTOM, (αy)BOTTOM, (αx)TOP, (αy)TOP, respectively of the platform position equations (2), (3). The cable angle computation circuits 94 of the channels perform these computations. More specifically, the cable angle computation circuit 94 of the lower cable angle input channel 88 is programmed to compute the lower cable angles (u,),,,,,, (n,),,,,,. The upper channel cable angle computation circuit 94 is programmed to compute the upper cable angles (αx)TOP, (αy)TOP.
The computed bottom cable angles (αx)BOTTOM, (αy)BOTTOM from the angle computation circuit 94 of the lower cable angle input channel 88 and the gain factor K2 from the gain factor determination means 92 are both input to the multiplier circuit 96 of the lower channel. The output from this multiplier circuit
are signals represenging the products K2(αx)BOTTOM and K2(av)aorro Similarly, the computed top cable angles (ax)op (a )ToP from the angle computation circuit 94 of the upper cable angle input channel 90 and the gain factor K1 from the gain factor determination means 92 are both input to the multiplier circuit 96 of the upper channel.The outputs from this multiplier circuit are signals representing the products K1(X)TOP’ K1(ay)op.
The signal outputs from the channel multipliers 96 are fed to the low-pass filter circuits 98. As explained presently, these filter circuits filter out higher order frequencies present in the cable angle signals from the cable slope angle sensors 36, 40 due to wave induced motion of the floating platform 10 which produce travelling stress waves or undulations in the cable 20. The filtered outputs from the multiplier circuits 94, 96 represent products, not of the instantaneous cable slope angles (αx)TOP, (αy)TOP, (αx)BOTTOM, (αy)BOTTOM, but rather products of the mean cable slope angles, i.e. the top and bottom slope angles of the cable envelope.
These filtered output signals from the multipliers 94, 96 are input to a state estimator 100. This state estimator is a simple adder which sums the filtered signal products K1(X)TOPS K1(αy)TOP, K2(αx)BOTTOM, K2(αy)BOTTOM in accordance with the platform position equations (2), (3) to obtain the platform position coordinates X,
Y. The state estimator output may be filtered at 102 to remove any remaining undesirable frequencies in the coordinate output signals.
As noted earlier, the connecting line between the floating platform 10 and the ocean floor 14 may be other than a cable. In Figure 6, for example, the platform 10a is an oil or gas well drilling or producing platform and the connecting line 20a is a riser extending from the platform to a well bore or head 30a on the ocean floor 14.
In the case of a drilling platform, a drill string (not shown) extends through the riser. In the case of an oil production platform, oil is pumped to the surface through the riser. The lower end of the riser 30a is coupled to the well head by joint 31a which may be a ball joint. The upper end of the riser is coupled by a second joint 31a which may also be a ball joint to a vertically movable conduit 33a on the platform 10a communicating to an oil pump, gas pump, or drilling mud pump (not shown) on the platform. Conventional riser tensioning means 22a coupled to the conduit 33a, are provided for sensing and regulating the riser tension to maintain a relatively constant tension in the riser. This tensioning means, for example, may be a cable tensioning means similar to that of Figure 1, wherein the cable 20 is attached to the conduit 33a to exert an upward pull on the riser 20a. Slope angle sensors 36a, 40a such as two-axis accelerometers or tilt-sensors similar to those in
Figure 1, are mounted on the riser at or near its ends. The system shown in Figure 6 is otherwise essentially identical to that of Figures 1–5.
The derivation of the position equations (2), (3) will now be explained by reference to Figure 4 and 5. Figure 4 is a graphical representation, in perspective, of the floating marine platform 10, the ocean Reference P, the flexible connecting line or cable 20, and the Cartesian coordinate system, X, Y, Z on which the position equations (2), (3) are based. Figure 5 illustrates the projection of the platform 10 and cable 20 onto the X-Z plane of the coordinate system.
In Figure 5, T1 and T2 are tangents to the upper and lower ends of the cable 20.
These tangents intersect at a point a. A line b is drawn through this intersection point a parallel to the X axis and a line c is drawn through the upper point d of tangency of the cable 20 and tangent T1, parallel to the Z axis. Lines b and c intersect one another at the point e and the Z and X axes, respectively, at points f and g. For all practical purposes, tangent point d is located at the ocean surface and intersection point g is located at the ocean floor 14.
It is evident from an inspection of Figure 5 that the angle aix between the tangent T1 and line C and the angle CE2x between the tangent T2 and the Z axis define the upper and lower vertical slope angles of the cable 20, as measured in the X plane. It will also be seen that these slope angles are angles of right triangles a, d, e and a, f, P, respectively. For convenience, the sides of triangle a, d, e are designated h1, X1, K1 and the sides of triangle a, f, p are designated h2, X2, K2.
Based on simple trigonometry, it is apparent that
X1
sin α1x=—- (4)
h,
X2
sin a2= (5)
h2
For small slope angles on the order of 10C or less, the following approximations are valid: K,=h,; K2=h2; sin a,x=a,x (in radians)
and
sin 2X=a!2x (in radians) (6)
Rewriting equations (4) and (5) taking into account the approximations (6), we
obtain:
X, a1 or X,=K,a, (7)
K1
X2 a2 or )C2=K2a2 (8)
K2
The X coordinate of the platform 10 is: X=Xa+X2=Krt1x+K2a2x (9)
It is evident that a similar analytical procedure based on the projection of the
platform 10 and cable 20 onto the y plane of the coordinate system would yield the
following equation: Y=K1α1y+K2α2y (10)
Where K1 and K2 are the same as in equation (9) and a lv’ aS2V are the upper and
lower vertical cable slope angles measured in the Y plane.
The above equations (9) and (10) are obviously the earlier position equations (2), (3) wherein the upper and lower cable slope angles are designated by the subscripts «top» and «bottom».
The procedure for determining the gain factors K1, K2 in the platform position equations (2), (3) will now be discussed. Assuming the physical characteristics of the connecting line 20, 20a to be such that the latter can be approximated by a uniform beam of negligible stiffness, i.e., negligible El (Young’s modulesxmoment of inertia), the gain factors Kl, K2 can be determined analytically as follows.
Consider first steady state conditions in which there are no waves or other variable forces acting on the platform 10, l0a or the connecting line 20, 20a and the connecting line tension is held constant. It can easily be demonstrated analytically that under these steady state conditions, the horizontal displacement (estimated) between the upper and lower ends of the connecting line may be expressed by the equations
where::
H=the horizontal displacement T6=bottom connecting line tension Ti=top connecting line tension bottom connecting line slope angle aT=top connecting line slope angle
D=water depth
The above equations (11) show that under the assumed steady state conditions, the horizontal displacement of the connecting line ends may be estimated or determined analytically using either the bottom or top connecting line slope angle alone.
An actual marine environment of the kind in which the invention is intended to be used is not a steady state environment, however, but rather a dynamic one in which the floating platform is subject to wave action. An important feature of this invention resides in the fact that it considers the dynamics of the platform system and marine environment and compensates or corrects for certain phase lag that such dynamics introduce into the system.
In this regard, consider an incremental horizontal motion of the floating platform 10, 10a due to wave action or manoeuvering of the platform to return the latter toward a desired horizontal position relative to the ocean floor reference position P. This horizontal platform motion causes corresponding lateral motion of the upper end of the connecting line relative to its lower end and thereby also a change in the top and bottom slope angles of the connecting line. These slope angles, however, do not change instantaneously with and in direct relation to the motion of the upper connecting line end in a manner such that the instantaneous slope angles accurately reflect the current relative horizontal positions of the connecting line ends and hence the horizontal position of the floating platform relative to the ocean floor reference P.Rather, the platform motion produces stresses or stress waves which propagate along the connecting line in the form of travelling undulations in line in much the same manner as travelling waves are produced in a long rope when one end of the rope is snapped. As a consequence, the platform motion is not reflected in a change in the bottom connecting line slope angle until the motion induced stress waves in the connecting line reach the lower slope angle sensor 36, 36a. Even then the lower connecting line end does not immediately assume a new steady state slope angle corresponding to the horizontal position of the platform at the end of the incremental platform motion which produced the slope angle change. Rather the bottom slope angle will fluctuate as the connecting line stress waves or undulations travel downwardly and then reflect upwardly past the bottom end slope angle sensor. The upper connecting line slope angle tends to change instantaneously with and in leading relation to platform motion. Slope angle fluctuations also occur at the upper end of the connecting line due to the travelling stress waves or undulations in the line.
It is evident from the foregoing discussion that in an actual dynamic marine environment in which the floating platform is subjected to wave action, the resulting wave induced motion of the platform produces complex stress waves or undulations in the connecting line which travel continuously back and forth along the line between the bottom and top slope angle sensors. The bottom and top connecting line slope angles, and hence also the slope angle outputs of the bottom and top slope angle sensors thus continuously fluctuate with a period or frequency related to the period of the surface waves about mean values which are related to the current horizontal position of the platform relative to the ocean floor reference
P and are effectively the slope angles of the envelope of the undulating connecting line.Further, owing to the transit time of the platform motion induced stress waves or undulations along the connecting line between the angle sensors, a phase lag exists between the output of the bottom slope angle sensor relative to that of the upper sensor.
As a consequence, in an actual marine platform installation according to this embodiment in which the dynamics of the platform system must be considered beeause of wave action, the slope angle outputs of the bottom and top slope angle sensors must be weighted to provide the proper phase relationship between sensor outputs. The gain factors K1, K2 in the position equations (2), (3) are scale factors which provide this weighting.
In order to analyze the phase characteristics of a given connecting line, the latter is modelled by a simple time delay T representing the transit time of platform motion induced stress waves between the bottom and top slope angle sensors > The output of the top sensor 40 is assumed to be proportional to the velocity, i.e. rate of slope angle change, of the upper end of the connecting line. Under these conditions, it can be shown that:
where: time phase angle of the top connecting line slope angle 1tT with respect to
the platform velocity
=angular frequency of platform oscillatory motion D, TT, TB are as defined in equation (if).
For any given platform and connecting line configuration, the values of t, can be determined in the manner described below. Accordingly, assuming these values for a particular platform and connecting line configuration of interest to be known, the above equations (12) and (13) provide one method for determining the gain or scale factors K, K2 which can then be used in the position equations (2), (3) to determine the horizontal position of the platform relative to the ocean floor reference.
If the physical characteristics of the connecting line are such that the simplifying assumptions used in the preceding development are not applicable, the gain or scale factors K, K2 can be determined empirically with the aid of an appropriate computer simulation procedure. Such a simulation procedure is described in ASME Publication No. 77-PET-39 reporting a presentation made at the Energy Technology Conference and Exhibit, Houston, Texas, September 1822, 1977. This simulation is based on and uses essentially the same equations as an earlier Mohole riser study reported in NESCO (National Engineering Science Co.)
Report No. 183-2A dated January 1965 and entitled «Dynamic Stress Analyses of the Mohole Riser System».While the ASME publication discusses the simulation in the context of a marine riser such as shown in Fig. 6 of the drawings, it will be obvious to those versed in the art that the simulation covers other forms of connecting lines, such as the cable in Figs. 1–5.
The procedure for determining the gain or scale factors K1, K2 using the connecting line simulation of the ASME publication involves the following steps:
1. Determine for the floating platform and connecting line of interest the critical physical characteristics involved in the ASME simulation.
2. Define for the environmental conditions involved in the ASME simulation the worst case values which are anticipated to be encountered.
3. Define the ranges of tension, mud weight (if appropriate) and water depth for the application of interest.
4. Use the data obtained in steps 1, 2 and 3 as input to the ASME connecting line simulation to generate the time histories of the motion of the upper connecting line end and of the top and bottom connecting line slope angles for particular input parameter combinations of interest.
5. For each case simulated in step 4, select a number of sets, preferably three, of gain factors K1, K2 and combine these factor sets and associated slope angle lime histories from step 4 in accordance with the position equations (2), (3) to obtain, for each selected gain factor set, the time history of the estimated horizontal position of the upper connecting line and relative to the lower end, e.g.:
x est (t)=K,aX(t)T+K2ctx(t)B (14)
y est (t)=K1ay(t)T+K2szv(t)B ( where::
x est (t)=the time history of the x coordinate of the upper connecting line end n,(t),=the time history of the top connecting line slope angle in the x-z plane ax(t)8=the time history of the bottom connecting line slope angle in the x-z plane
y est (t)=the time history of the y coordinate of the upper connecting line end ev(t)T=the time history of the top connecting line slope angle in the y-z plane a,(t)8=the time history of the bottom connecting line slope angle in the y-z plane
6.Use the Fourier transform to obtain amplitude and phase plots for the estimated top connecting line end position time histories obtained in step 5 for each selected gain factor set K» K2, and amplitude and phase plots for the associated top connecting line end position time histories obtained in step 4 by the ASME simulation procedure,
7. Select the gain factors K,, K2 which yield estimated top connecting line end time histories having the preferred amplitude and phase characteristics relative to the simulation generated position time histories obtained in step 4.
In this latter regard, the gain factors K1, K2 are preferably selected such that the estimated horizontal position of the top connecting line end relative to the bottom end has the following characteristics:
(I) The difference in magnitude between the actual and estimated positions of the connecting line ends is preferably less than 1 / of water depth for forcing functions, i.e., surface waves, with periods of 100 seconds and greater.
(2) The phase of the estimated upper connecting line end position preferably leads that of the actual position by a small amount. In a worst case condition, the estimated position must not lag the actual position by more than 5″.
The procedure defined by the foregoing steps 1–7 yields sets of corresponding values for the gain factors K1, K2 for the various parameter combinations of interest selected in step 4 for computer simulation.
Two different techniques have thus been explained for obtaining the gain factors K1, K2 for use in the platform position equations (2), (3). One of these techniques is represented by equations (12), (13) and involves solution of these equations for particular values of , w, T which may be determined in the manner discussed below. The other technique is represented by the combined position simulation/estimation procedure defined by the foregoing steps 1–7 and yields a series of optimum gain factor values corresponding to different environmental, platform and connecting line parameters of interest.
The gain factor determination means 92 may be a computer for solving the gain factor equations (12), (13). In this case, the operator keyboard 46 may have means for selectively presetting into the computer 92 input data representing the values of p , T for selected platform/connecting line system and sea spectrum involved. The computer 92 will be programmed to operate on this data in accordance with the equations (12), (13) and to input to the connecting line angle input channel multipliers 96 the corresponding factor values K1, K2 respectively.
Alternatively, the gain factor determination means 92 may comprise a memory in which are stored the various gain factors obtained by the ASME simulation/estimation procedure described earlier and from which the gain factors corresponding to any selected parameter combination used in step 4 of the procedure may be read out in the form of corresponding gain factor signals by inputting to the memory data representing the selected parameter combination. In this case, the operator keyboard 46 will include means of selectivity inputting such parameter data to the memory. Thus, in system operation, the keyboard operator will actuate the keyboard to input to or address the memory 92 with parameter data corresponding to the current ocean and/or other environmental conditions of interest.The memory will respond to this input data by reading out the corresponding gain factors K1, K2 to the slope angle input channel multipliers 96.
Following is a table of representative gain factors for a drill string/riser combination through which drilling mud is circulated during the drilling operation.
Representative K, and K2 Table
Water Depth (D) Mud Weight Tension
(Feet) (Ibs/gal) (10001bus) K,/D K2/D
4500 20 650 .857 .143
4500 20 800 .79 .21
4500 20 950 .750 .250
It will now be understood that during operation of the platform position determining system of the invention, the top and bottom slope and azimuth angles of the connecting line 20, 20a are measured and converted, in the slope angle computers 94, to signals representing the top and bottom connecting line slope
angles (afx)TOPs (),,,, (ax)ono, (cr,),,,,,, used in the platform position equations (2), (3).These latter slope angles are fed to the slope angle input channel multipliers 96 along with signals from the gain factor determining means 92 representing the gain factors K1, K2 corresponding to the current system parameter input data from the keyboard 46. The multipliers 96 obtain and output to the low pass channel filters 98 signals representing the products K1(X)TOPS K2(X)BOTTOMS K1(CI!V)TOPS K2(Y)BOTTOM- Filters 98 are tuned to filter out higher order frequencies present in the product signals from the multipliers 96 resulting from wave induced motion of the platform 10, 10a which does not result in any net change in the platform position.
Typically, these filters have a high side-cut-off frequency on the order of 1/4 cycles per second. Accordingly, the filtered output signals from the channel filters 98 are effectively the products of the gain factors K1, K2 and the mean top and bottom connecting live slope angles, i.e. the top and bottom slope angles of the envelope of the undulating connecting line configuration produced by the wave motion.
The filtered product signals from the filters 98 are fed to the estimater 100 which adds the products in accordance with the position equations (2), (3) and outputs signals representing the corresponding X and Y coordinates of the platform. The coordinate signals from the estimator 100 may be further filtered by the filter 102 to further suppress high frequency forcing functions, such as wave action, which create no net change in the platform position.
As mentioned, equations (12), (13) may be used to determine the platform position if the quantities A, , T are known. These quantities may be determined for a given platform connecting line system and sea spectrum of interest as follows.
The phase angle p may be determined by using the earlier mentioned simulation procedure to generate the time histories of the platform motion and upper connecting line slope angle and from these time histories determining the phase angle (/3) of the upper slope angle relative to the platform motion. The quantity T is determined by dividing the connecting line length by the square root of the ratio of the connecting line mass per unit length to the connecting line tension.The quantity a) may be determined by solving the equations (12), (13) for the scale factors K1, K2 for a range of a) values using the p and T values determined as above for the particular platform/connecting line system and sea spectrum of interest and selecting the a) value which yields scale factors equalling or most closely approximating the scale factors obtained by .the earlier described simulation/estimation procedure based on the same platform/connecting line system and sea spectrum.By way of example, it was found that for one simulated platform/connecting line system and sea spectrum, the phase angle p remained nearly constant at 30 over a wide range of water depths and connecting line tensions for a range of wave periods from 100 seconds to 400 seconds. In this simulation, an c() value of 0.0628 provided good correlation between the scale factor values obtained by computation using equations (12), (13) and the scale factors obtained by computed simulation.
As mentioned earlier and shown in the drawings, the platform position signals from the estimator 100 are fed to the platform positioning system 18. This positioning system may comprise any suitable positioning system, such as that described in Pat. No. 3,730,126 for propelling the platform 10 to maintain the latter in a desired horizontal position relative to the ocean floor Reference P.
WHAT WE CLAIM IS:
1. A system for determining the relative horizontal positions of the upper and lower ends of a flexible connecting line suspended from a floating marine platform, and wherein the length of said line is many orders of magnitude greater than the relative horizontal displacement of the connecting line ends, said system comprising::
angle sensing means including upper and lower connecting line angle sensors for producing angle signals representing the vertical slope angles and azimuth angles of the upper and lower ends of said connecting line, and
signal processing means for combining said angle signals in accordance with a predetermined relationship of said slope angles which compensates for phase difference between the sensor outputs due to the propagation time of stress waves through said line to provide an output signal representing said relative horizontal positions.
2. A system for determining the relative horizontal positions in terms of a cartesian coordinate system having a vertical Z axis and horizontal X and Y axes of the upper and lower ends of a flexible connecting line suspended from a floating marine platform, comprising:
angle sensing means including upper and lower connecting line angle sensors for producing angle signals representing the vertical slope angles of the upper and lower ends of said connecting line measured in vertical X planes parallel to said X and Z axes and vertical Y planes parallel to said Y and Z axes, and
signal processing means for combining said angle signals in accordance with the following equations (1) and (2) to provide an output signal representing the relative horizontal positions of said connecting line ends in terms of the X and Y coordinates of the upper end relative to the lower end X=K1(Ctx)ToP+K2(eX)BOTTOM (1) Y= K1(ay)op+K2(ay)soo (2)
where: (ax)op, (a,),,,,,, are the upper and lower vertical slope angles of the
connecting line measured in said X planes, respectively, (n,),,,, (aV)BOTTOM are the upper and lower vertical slope angles of the
connecting line measured in said Y planes, respectively,
K1, K2 are scale factors which are dependent upon at least some of the
following: surface wave spectrum; physical characteristics of the
connecting line including tension, modulus of elasticity, moment of
inertia, drilling mud weight if used, and transit time of platform motion
induced stress waves through the connecting line; physical characteristics
of the platform; water current.
3. The system of claim 2 wherein:
said scale factors equal:
**WARNING** end of DESC field may overlap start of CLMS **.
Claims (22)
**WARNING** start of CLMS field may overlap end of DESC **. tensions for a range of wave periods from 100 seconds to 400 seconds. In this simulation, an c() value of 0.0628 provided good correlation between the scale factor values obtained by computation using equations (12), (13) and the scale factors obtained by computed simulation. As mentioned earlier and shown in the drawings, the platform position signals from the estimator 100 are fed to the platform positioning system 18. This positioning system may comprise any suitable positioning system, such as that described in Pat. No. 3,730,126 for propelling the platform 10 to maintain the latter in a desired horizontal position relative to the ocean floor Reference P. WHAT WE CLAIM IS:
1. A system for determining the relative horizontal positions of the upper and lower ends of a flexible connecting line suspended from a floating marine platform, and wherein the length of said line is many orders of magnitude greater than the relative horizontal displacement of the connecting line ends, said system comprising::
angle sensing means including upper and lower connecting line angle sensors for producing angle signals representing the vertical slope angles and azimuth angles of the upper and lower ends of said connecting line, and
signal processing means for combining said angle signals in accordance with a predetermined relationship of said slope angles which compensates for phase difference between the sensor outputs due to the propagation time of stress waves through said line to provide an output signal representing said relative horizontal positions.
2. A system for determining the relative horizontal positions in terms of a cartesian coordinate system having a vertical Z axis and horizontal X and Y axes of the upper and lower ends of a flexible connecting line suspended from a floating marine platform, comprising:
angle sensing means including upper and lower connecting line angle sensors for producing angle signals representing the vertical slope angles of the upper and lower ends of said connecting line measured in vertical X planes parallel to said X and Z axes and vertical Y planes parallel to said Y and Z axes, and
signal processing means for combining said angle signals in accordance with the following equations (1) and (2) to provide an output signal representing the relative horizontal positions of said connecting line ends in terms of the X and Y coordinates of the upper end relative to the lower end X=K1(Ctx)ToP+K2(eX)BOTTOM (1) Y= K1(ay)op+K2(ay)soo (2)
where: (ax)op, (a,),,,,,, are the upper and lower vertical slope angles of the
connecting line measured in said X planes, respectively, (n,),,,, (aV)BOTTOM are the upper and lower vertical slope angles of the
connecting line measured in said Y planes, respectively,
K1, K2 are scale factors which are dependent upon at least some of the
following: surface wave spectrum; physical characteristics of the
connecting line including tension, modulus of elasticity, moment of
inertia, drilling mud weight if used, and transit time of platform motion
induced stress waves through the connecting line; physical characteristics
of the platform; water current.
3. The system of claim 2 wherein:
said scale factors equal:
where:
D=water depth TB=bottom connecting line tension TT=top connecting line tension /3=time phase angle of the top connecting line slope angle with respect to the
platform velocity
w=angular frequency of platform oscillatory motion
2=propagation time of stress waves through line.
4. The system of claim 2 wherein:
said scale factors are determined for a given platform/connecting line system
and marine conditions of interest by comparing estimated platform X and Y
coordinates obtained by solution of said equations (1) and (2) using arbitrary scale
factor values with simulated platform X and Y coordinates obtained by computer
simulation of the response of said platform/connecting line system to said marine
conditions, and selecting the numerical scale factor values which yield the best
correlation between the estimated and simulated coordinates.
5. The system of claim I wherein:
said signal processing means includes low pass filter means for attenuating
higher signal frequencies resulting from wave induced motion of said platform.
6. The system of claim 2 wherein:
said signal processing means comprises means for providing scale factor
signals representing selected scale factor values, means for receiving said angle and
scale factor signals and producing product signals representing the products qf the
corresponding slope angles and scale factors according to saidequations (1), (2)
means for summing said product signals according to said equations (1), (2) and
producing said output signal representing said X, Y coordinates, and low pass filter
means for attenuating higher order frequency components present in said signals
due to wave induced platform motion.
combining said angle signals in accordance with the following equations (1) and (2) to provide an output signal representing the relative horizontal positions of said connecting line ends in terms of the X and Y coordinates of the upper end relative to the lower end X= K1(( Fx)Top+K2((x)BoTToM ( I ) Y=K1(ct)Top+K2(tts)soTToM (2)
where: (ax)op. (a,),,,,, are the upper and lower vertical slope angles of the
connecting line measured in said X planes, respectively, (gy)TOpl (aY)BOTTOM are the upper and lower vertical slope angles of the
connecting line measured in said Y planes, respectively,
K1, K2 are scale factors which are dependent upon at least some of the
following: surface wave spectrum; physical characteristics of the
connecting line including tension, modulus of elasticity, moment of
inertia, drilling mud weight if used, and transit time of platform motion
induced stress waves through the connecting line; physical characteristics
of the platform; water current.
7. The method of determining the relative horizontal positions of the upper
and lower ends of a flexible connecting line suspended from a floating marine
platform, and wherein the length of said line is many orders of magnitude greater
than the relative horizontal displacement of the connecting line ends, said system,
comprising:
sensing and producing angle signals representing the vertical slope angles and
azimuth angles of the upper and lower ends of said connecting line, and
combining said angle signals in accordance with a predetermined relationship
of said slope angles which compensates for phase difference between the sensor
outputs due to the propagation time of stress waves through said line to provide
output signal means representing said relative horizontal positions.
8. The method of determining the relative horizontal positions in terms of a
cartesian coordinate system having a vertical Z axis and horizontal X and Y axes of
the upper and lower ends of a flexible connecting line suspended from a floating
marine platform, comprising:
sensing and producing angle signals representing the vertical slope angles of the upper and lower ends of said connecting line measured in vertical X planes parallel to said X and Z axes and vertical Y planes parallel to said Y and Z axes, and
9.The method of claim 8 wherein:
said scale factors equal:
where:
D=water depth TB=bottom connecting line tension TT=top connecting line tension /3=time phase angle of the top connecting line slope angle with respect to the
platform velocity
w=angular frequency of platform oscillatory motion
T=propagation time of stress waves through line
10.The method of claim 8 wherein:
said scale factors are determined for a given platform/connecting line system and marine conditions of interest by comparing estimated platform X and Y coordinates obtained by solution of said equations (1) and (2) using arbitrary scale factor values with simulated platform X and Y coordinates obtained by computer simulation of the response of said platform/connecting line system to said marine conditions, and selecting the numerical scale factor values which yield the best correlation between the estimated and simulated coordinates.
11. The method of claim 8 wherein: filtering said signals to attenuate higher signal frequencies resulting from wave induced motion of said platform.
12. The method of claim 8 wherein: said signal combining step comprises providing scale factor signals representing selected scale factor values, producing product signals representing the products of the corresponding slope angles and scale factors according to said equations (1), (2), summing said product signals according to said equations (1), (2) and producing said output signal representing said X, Y coordinates, and filtering said signal to attenuate higher order frequency components present in said signals due to wave induced platform motion.
13. A system of positioning a floating marine platform relative to a reference position on the ocean floor comprising: a flexible connecting line extending between said platform and reference position, angle sensing means including upper and lower connecting line angle sensors for sensing and producing angle signals representing the vertical slope angles and azimuth angles of the upper and lower ends of said connecting line, signal processing means for combining said signals in accordance with a predetermined relationship and producing an output signal representing the horizontal position of said platform to said reference position, and means for horizontally positioning said platform in response to said signal.
14. A system according to claim 13 wherein said signal processing means comprises a first analog-to-digital converter means for receiving, combining, and converting an upper angle signal to provide a converted upper angle signal a d.c.
power supply means for providing a calibration signal; a timing and control logic means for providing first, second, and third timing and control signals respectively; an analog multiplexer means for receiving and combining said calibration signal, said first timing and control signal, and a lower angle signal to provide a composite signal, a second analog-to-digital converter means for receiving and combining said composite signal and said second timing and control signal to provide a converted lower angle signal; a modem means for receiving and combining said converted lower angle signal and said third timing and control signal to provide a digital information signal; a conditioning means for receiving and conditioning said converted upper angle signal and said digital information signal to provide a conditioned data signal and a data ready signal, respectively, to said signal processing means; and a keyboard means for entry of cable, platform, and marine parameters to provide a system parameter signal to said signal processing means; said processing means providing an output signal to said positioning system and a read out signal to a digital read out.
15. A system according to claim 14, in which said digital read-out displays the coordinants of said platform.
16. A system according to claim 14, in which said digital read-out displays said cable, platform, and marine parameters.
17. A system according to claim 14, in which said modem means includes an up link modulator and cable driver means for providing an up link signal to a demodulator means which provides said digital information signal.
18. A method of positioning a floating marine platform relative to a reference position on the ocean floor comprising: sensing and producing angle signal representing the vertical slope angles and azimuth angles of the upper and lower ends of a flexible connecting line extending between said platform and reference position, combining said signals in accordance with a predetermined relationship and producing an output signal representing the horizontal position of said platform relative to said reference position, and horizontally positioning said platform in response to said signal.
19. A system for determining the relative horizontal positions of the upper and lower ends of a flexible connecting line suspended from a floating marine platform substantially as herein described with reference to and as illustrated in the accompanying drawings.
20. A method for determining the relative horizontal positions of the upper and lower ends of a flexible connecting line suspended from a floating marine platform substantially as herein described with reference to and as illustrated in the accompanying drawings.
21. A system for positioning a floating marine platform relative to a reference position on the ocean floor substantially as herein described with reference to and as illustrated in the accompanying drawings.
22. A method of positioning a floating marine platform relative to a reference position on the ocean floor substantially as herein described with reference to and as illustrated in the accompanying drawings.
GB19617/78A
1977-05-16
1978-05-15
Position determining and dynamic positioning method and system for floating marine well drilling platforms and the like
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Position determining and dynamic positioning method and system for floating marine well drilling platforms and the like
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GB2348714A
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*
1999-04-06
2000-10-11
Mitsui Shipbuilding Eng
Method and apparatus for controlling the position of a floating rig
CN111577244A
(en)
*
2020-05-12
2020-08-25
中国海洋石油集团有限公司
Real-time monitoring method for drilling riser top dip angle and top joint corner
1978
1978-05-15
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Publication date
Assignee
Title
GB2348714A
(en)
*
1999-04-06
2000-10-11
Mitsui Shipbuilding Eng
Method and apparatus for controlling the position of a floating rig
GB2348714B
(en)
*
1999-04-06
2001-08-08
Mitsui Shipbuilding Eng
Method and apparatus for controlling the position of floating rig
US6278937B1
(en)
1999-04-06
2001-08-21
Mitsui Engineering & Shipbuilding Co., Ltd.
Method and apparatus for controlling the position of floating rig
CN111577244A
(en)
*
2020-05-12
2020-08-25
中国海洋石油集团有限公司
Real-time monitoring method for drilling riser top dip angle and top joint corner
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1981-06-03
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Patent sealed [section 19, patents act 1949]
1982-12-15
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Patent ceased through non-payment of renewal fee