Method of laying a pipeline from a laying vessel onto the bed of a body of water, and laying vessel

Abstract

A method of laying a pipeline from a laying vessel into a body of water includes guiding the pipeline along a supporting structure of a laying ramp. The method also includes acquiring a first data item correlated to a position of the pipeline at a free end of the laying ramp using an optical sensor or an acoustic sensor. The method further includes determining whether the acquired first data item is within an acceptance range predetermined as a function of a configuration of the supporting structure and a size of the pipeline. Additionally, the method includes emitting an control signal when the acquired first data item is not within the acceptance range. Determining whether the acquired first data item is within the acceptance range includes processing the acquired first data item to compare it the first data item to an information stored in a memory.

Claims

1. A method of laying a pipeline from a laying vessel into a body of water, the method comprising: guiding the pipeline along a supporting structure of a laying ramp; acquiring a first image of a first face of the pipeline and a second image of a second face of the pipeline in a same acquisition plane as the first image, the acquisition plane being crosswise to an axis of the pipeline; determining whether the acquired first image and the acquired second image are within respective acceptance ranges predetermined as a function of a configuration of the supporting structure and a size of the pipeline; emitting a control signal when at least one of the acquired first image and the acquired second image is not within the respective acceptance range; and determining a distance between the pipeline and the supporting structure at a free end of the laying ramp; wherein determining whether the acquired first image and the second image are within the respective acceptance ranges comprises processing the acquired first image and the acquired second image to compare the acquired first image and the acquired second image to information stored in a memory.

2. The method as claimed in claim 1, further comprising adjusting the guiding of the pipeline with respect to the supporting structure as a function of the control signal.

3. The method as claimed in claim 1, further comprising altering a configuration of the supporting structure as a function of the control signal.

4. The method as claimed in claim 1, further comprising controlling a position of the laying vessel as a function of the control signal.

5. The method as claimed in claim 1, further comprising controlling a force exchanged between a tensioning device and the pipeline, so as to control pull exerted on the pipeline as a function of the control signal.

6. The method as claimed in claim 1, wherein the first image is an acoustic image of the first face of the pipeline, and wherein the second image is an acoustic image of the second face of the pipeline.

7. The method as claimed in claim 1, wherein the first image is an optical image of the first face of the pipeline, and wherein the second image is an optical image of the second face of the pipeline.

8. The method as claimed in claim 1, wherein the information stored in the memory is a real image or a modeled image reconstructed based on known dimensions of the pipeline.

9. A laying vessel for laying a pipeline in a body of water, the laying vessel comprising: a laying ramp comprising a supporting structure and a plurality of guide devices configured to guide the pipeline; a first image acquisition device configured to acquire a first image of a first face of the pipeline; a second image acquisition device configured to acquire a second image of a second face of the pipeline, the first image and the second image being in a same acquisition plane crosswise to an axis of the pipeline, in the body of water; and a control unit configured to determine whether the acquired first image and the acquired second image are within respective acceptance ranges predetermined as a function of a configuration of the supporting structure and a size of the pipeline by processing the acquired first image and the acquired second image to compare the first image and the second image to information stored in a memory, emit a control signal when the acquired first image or the acquired second image is not within the respective acceptance range, and determine the distance between the pipeline and the supporting structure at the free end of the laying ramp.

10. The laying vessel as claimed in claim 9, further comprising a control device connected to the control unit, configured to control a variable configuration of the guide devices, and configured to alter the configuration of the guide devices with respect to the supporting structure as a function of the control signal.

11. The laying vessel as claimed in claim 9, further comprising: a drive assembly configured to alter a configuration of the laying ramp; and a control device configured to control the drive assembly as a function of the control signal.

12. The laying vessel as claimed in claim 9, further comprising: a floating structure; a J-lay tower hinged to the floating structure; a drive assembly configured to alter a configuration of the J-lay tower; and a control device configured to control the drive assembly and the configuration of the J-lay tower as a function of the control signal.

13. The laying vessel as claimed in claim 9, further comprising a control device connected to the control unit and configured to control a position of the laying vessel as a function of the control signal.

14. The laying vessel as claimed in claim 9, further comprising: a tensioning device configured to exchange a force with the pipeline and exert pull on the pipeline; and a control device connected to the control unit and configured to control the force exchanged between the tensioning device and the pipeline so as to control the pull exerted on the pipeline as a function of the control signal.

15. The laying vessel as claimed in claim 9, wherein the control unit is configured to determine a distance between the pipeline and the supporting structure at the free end of the laying ramp.

16. The laying vessel as claimed in claim 9, wherein the first image acquisition device and the second image acquisition device each comprise a sensor fitted to the laying ramp to define a fan-shaped acquisition range extending along the acquisition plane; and a processing unit.

17. The laying vessel as claimed in claim 9, wherein the first image acquisition device and the second image acquisition device each comprise a light source configured to emit a laser beam that sweeps a whole face of the pipeline along the acquisition plane.

18. A laying vessel for laying a pipeline in a body of water, the laying vessel comprising: a laying ramp comprising a supporting structure and a plurality of guide devices configured to guide the pipeline; a first image acquisition device configured to acquire a first image of a first face of the pipeline; a second image acquisition device configured to acquire a second image of a second face of the pipeline, the first image and the second image being in the same acquisition plane crosswise to an axis of the pipeline, in the body of water; and a control unit comprising a memory, and configured to determine whether the acquired first image and the acquired second image are within respective acceptance ranges stored in the memory, emit a control signal when the acquired first image or the acquired second image is not within the respective acceptance range, and determine a distance between the pipeline and the supporting structure at the free end of the laying ramp.

19. A laying vessel for laying a pipeline in a body of water, the laying vessel comprising: a laying ramp comprising a supporting structure and a plurality of guide devices configured to guide the pipeline; a first image acquisition device configured to acquire a first image of a first face of the pipeline; a second image acquisition device configured to acquire a second image of a second face of the pipeline, the first image and the second image being in a same acquisition plane crosswise to an axis of the pipeline, in the body of water; a memory configured to store a first acceptance range for the acquired first image and a second acceptance range for the second acquired image; and a control device configured to adjust guiding of the pipeline along the supporting structure as a function of the acquired first image, the acquired second image, and the first and second acceptance ranges stored in the memory, and determine a distance between the pipeline and the supporting structure at the free end of the laying ramp.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) A number of non-limiting embodiments of the present invention will be described by way of example with reference to the accompanying drawings, in which:

(2) FIG. 1 shows a partly sectioned side view, with parts removed for clarity, of a laying vessel equipped with a laying ramp and in accordance with the present invention;

(3) FIG. 2 shows a schematic cross section, with parts removed for clarity, of the FIG. 1 laying ramp;

(4) FIG. 3 shows a partly sectioned side view, with parts removed for clarity, of a laying vessel equipped with a laying ramp and in accordance with a further embodiment of the present invention;

(5) FIG. 4 shows a schematic cross section, with parts removed for clarity, of the FIG. 3 laying ramp.

DETAILED DESCRIPTION

(6) Number 1 in FIG. 1 indicates a laying vessel for laying a pipeline 2 on the bed (not shown) of a body of water of level SL. In the example shown, laying vessel 1 is a single-hull S-lay ship, and comprises a hull 3; an aftercastle 4; and an assembly line 5 for assembling pipeline 2 from pipes (not shown). Laying vessel 1 is equipped with a laying ramp 6, which defines an extension of assembly line 5 in the FIG. 1 operating configuration, and serves to guide and support pipeline 2 along a path having at least one curved portion, a first portion above water level SL, and a second portion below water level SL.

(7) Laying vessel 1 is equipped, at aftercastle 4, with a crane 7 for performing auxiliary pipeline 2 laying operations.

(8) Laying ramp 6 is hinged to laying vessel 1, and comprises an inner ramp 8 hinged to laying vessel 1, and an outer ramp 9 hinged to inner ramp 8. And laying vessel 1 comprises a drive assembly 10 for setting laying ramp 6 to a number of operating configurations (only one shown in FIG. 1); a transit configuration (not shown), in which both inner and outer ramps 8, 9 are positioned above water level SL; and a survival configuration (not shown in FIG. 1), in which inner and outer ramps 8, 9 are locked as far as possible above water level SL.

(9) Drive assembly 10 comprises two actuators 11, 12 for supporting, controlling, and setting respective inner and outer ramps 8, 9 to the above configurations. In the FIG. 1 laying configuration, inner ramp 8 and outer ramp 9 define respective supporting portions for pipeline 2.

(10) Laying ramp 6 comprises a supporting structure 13, and a number of guide devices 14 spaced along supporting structure 13. In the example shown, inner ramp 8 comprises an inner portion of supporting structure 13, and outer ramp 9 comprises an outer portion of supporting structure 13 hinged to the inner portion of supporting structure 13.

(11) T1 in FIG. 1 indicates a tensioning device, which exchanges a force, preferably a gripping force, with pipeline 2 to exert pull on pipeline 2 to release pipeline 2 from laying vessel 1 in controlled manner, or pull back pipeline 2, or lock pipeline 2 with respect to laying vessel 1.

(12) With reference to FIG. 2, supporting structure 13 extends along three sides defining a space housing pipeline 2. More specifically, FIG. 2 shows the free end of supporting structure 13, where the relative movements between pipeline 2 and laying ramp 6 are greatest. The guide device 14 at the free end of supporting structure 13 does not usually contact pipeline 2, and serves to absorb any shock. Each guide device 14 is damped with respect to supporting structure 13, and has actuators (not shown) for adjusting its active position with respect to supporting structure 13 to optimize load distribution between pipeline 2 and laying ramp 6.

(13) With reference to FIG. 1, laying vessel 1 comprises an image acquisition device 15, in turn comprising a sensor 16, and a processing unit 17 associated with sensor 16.

(14) Laying vessel 1 comprises a control device 18 for controlling drive assembly 10 of laying ramp 6; a control device 19 for controlling guide devices 14; a control device 20 for controlling the position of laying vessel 1—in the example shown, for controlling the dynamic positioning system comprising a number of thrusters 21 (only one shown in FIG. 1); a control device CT1 for controlling tensioning device T1 to adjust the force exchanged between pipeline 2 and tensioning device T1 and, therefore, the pull exerted on the pipeline; and a control unit 22 connected to image acquisition device 15 and control devices 18, 19, 20, and in turn comprising a display 23, a control panel 24, and a memory 25.

(15) With reference to FIG. 2, sensor 16 is fitted to supporting structure 13, at the free end of laying ramp 6, is positioned facing the outer face of pipeline 2, and is designed to define a fan-shaped image acquisition range lying substantially in an acquisition plane perpendicular to the axis of pipeline 2. Sensor 16 is defined by an optical sensor, so image acquisition device 15 preferably comprises a light source 26 fixed to supporting structure 13 to illuminate pipeline 2 in the image acquisition range of sensor 16; and an image processing unit 17 for processing optical images. In a variation, sensor 16 is defined by a sonar, and image processing unit 17 is designed to process acoustic images, so light source 26 is not needed.

(16) Light source 26 is preferably designed to emit a laser beam clearly showing pipeline 2 in the acquisition plane. More specifically, the laser beam is positioned and designed to sweep the whole face of the pipeline in the acquisition plane.

(17) With reference to FIG. 1, the images acquired by image acquisition device 15 are transmitted to control unit 22, where they are compared with images stored in memory 25. The stored images are acceptable real images of the known pipeline 2, or image models reconstructed on the basis of the known dimensions of pipeline 2. In a first comparison mode, the acquired images are compared with the stored images to determine the position of pipeline 2 with respect to the supporting structure, and to determine the X and Y coordinates, which are in turn compared with an acceptance range AR expressed in coordinates.

(18) In a second mode, the stored images define acceptance range AR.

(19) In both modes, control unit 22 emits an error signal E when pipeline 2 does not fall within the acceptance range AR defined substantially by the dash line in FIG. 2. With reference to FIG. 1, the error signal E may be used to correct the configuration of laying ramp 6 and/or guide devices 14, and/or the position of laying vessel 1, and/or the pull exerted on pipeline 2 by tensioning device T1. In other words, control unit 22 is able to automatically control devices 18, 19, 20, CT1 as a function of error signal E and other incoming signals relating to the load transmitted by pipeline 2 to guide devices 14, and to dynamic positioning of laying vessel 1.

(20) Control unit 22 may be set to only operate automatically on some of control devices 18, 19, 20, CT1.

(21) As shown in FIG. 2, laying ramp 6 is also equipped with a further image acquisition device 15 comprising a sensor 16, an image processing unit 17, and a light source 26 in the event sensor 15 is defined by an optical sensor. The further image acquisition device 15 is positioned to acquire images of pipeline 2 in the same acquisition plane as the other image acquisition device 15, but from a different angle. The images acquired by both image acquisition devices 15 are sent to control unit 22 for comparison with respective acceptance ranges, and an error signal E is emitted when the images acquired by at least one image acquisition device 15 do not fall within the respective acceptance range AR. As a result, image acquisition is made more dependable, and the range within which reliable images can be acquired is increased.

(22) The images acquired by both image acquisition devices 15 may also be combined to reconstruct the position of pipeline 2 with respect to laying ramp 6, and determine the distance of the pipeline from laying ramp 6 in the acquisition plane.

(23) Number 27 in FIG. 3 indicates as a whole a semisubmersible laying vessel comprising a double-hull floating structure 28; a hinge assembly 29; a J-lay tower 30 hinged to floating structure 28 by hinge assembly 29; and a drive assembly 31 for orienting J-lay tower 30 about the hinge axis into a number of configurations. The top part of J-lay tower 30 houses an assembly line 32 for assembling pipes (not shown); and the bottom part houses a tensioning device T2 for exchanging a force, preferably a gripping force, with the pipeline, to exert pull on pipeline 2 to release pipeline 2 in controlled manner, or pull back pipeline 2, or lock the pipeline with respect to laying vessel 27.

(24) The bottom end of J-lay tower 30 is connected to a laying ramp 34, which defines an extension of J-lay tower 30 and, in use, is immersed in the body of water. Laying ramp 34 is connected rigidly to J-lay tower 30, so the configuration of J-lay tower 30 determines the configuration of laying ramp 34.

(25) Laying ramp 34 comprises a supporting structure 35 extending about pipeline 2; and a number of guide devices 36, which are fitted to supporting structure 35, are spaced about pipeline 2 and along supporting structure 35, and are preferably adjustable and controllable by actuators not shown in the drawings.

(26) Laying ramp 34 is equipped with an image acquisition device 15 located at the free end of supporting structure 35 to determine any risk positions of pipeline 2 with respect to laying ramp 34.

(27) Images are acquired in the same way as described for laying ramp 6.

(28) Laying vessel 27 comprises a control unit 37; a control device 38 for controlling drive assembly 31; a control device 39 for controlling guide devices 36; a control device 40 for controlling the movement of laying vessel 27—in this case, dynamic positioning by means of thrusters 41 (only one shown in FIG. 2); and a control device CT2 for controlling the force exchanged between tensioning device T2 and pipeline 2, and therefore the pull exerted on the pipeline. As described with reference to FIG. 1, the acquired images are compared with an acceptance range AR, and control unit 37 emits an error signal E when the acquired images do not fall within acceptance range AR. Control unit 37 comprises a display 42, a control panel 43, and a memory 44, and is designed to both automatically and manually control the position of J-lay tower 30, and/or the position of guide devices 36, and/or the movement of laying vessel 27, and/or the pull exerted on pipeline 2, as a function of error signal E.

(29) As shown in FIG. 4, sensor 16 is fitted to supporting structure 35, at the free end of laying ramp 34, and positioned facing the outer face of pipeline 2. In this case, supporting structure 35 completely surrounds pipeline 2, and sensor 16 defines a fan-shaped image acquisition range lying substantially in an acquisition plane perpendicular to the axis of pipeline 2. Sensor 16 is defined by an optical sensor, so image acquisition device 15 preferably comprises a light source 26 fixed to supporting structure 35 to illuminate pipeline 2 in the image acquisition range of sensor 16; and an image processing unit 17 for processing optical images. In a variation, sensor 16 is defined by a sonar, and image processing unit 17 is designed to process acoustic images, so light source 26 is not needed.

(30) As shown in FIG. 4, laying ramp 34 is also equipped with a further image acquisition device 15 comprising a sensor 16, an image processing unit 17, and a light source 26 in the event sensor 15 is defined by an optical sensor. The further image acquisition device 15 is positioned to acquire images of pipeline 2 in the same acquisition plane as the other image acquisition device 15, but from a different angle. The images acquired by both image acquisition devices are processed in the same way as in the previous embodiment.

(31) The main advantages of the present invention lie in preventing the pipeline from assuming critical positions with respect to the laying ramp; enabling immediate intervention to counteract any critical situations; and fairly accurately determining the position of the pipeline with respect to the laying ramp, both in and out of the water.

(32) Clearly, changes may be made to the embodiments of the present invention described herein without, however, departing from the protective scope of the accompanying Claims. For example, ramp 6 may be formed in one rigid piece, or comprise any number of hinged portions.