US20130220203A1 - Platform Topside for an Offshore Platform and Method for Installing Such a Platform Topside - Google Patents
Platform Topside for an Offshore Platform and Method for Installing Such a Platform Topside Download PDFInfo
- Publication number
- US20130220203A1 US20130220203A1 US13/757,072 US201313757072A US2013220203A1 US 20130220203 A1 US20130220203 A1 US 20130220203A1 US 201313757072 A US201313757072 A US 201313757072A US 2013220203 A1 US2013220203 A1 US 2013220203A1
- Authority
- US
- United States
- Prior art keywords
- legs
- platform
- topside
- substructure
- platform topside
- Prior art date
- 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.)
- Abandoned
Links
Images
Classifications
-
- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02B—HYDRAULIC ENGINEERING
- E02B17/00—Artificial islands mounted on piles or like supports, e.g. platforms on raisable legs or offshore constructions; Construction methods therefor
- E02B17/02—Artificial islands mounted on piles or like supports, e.g. platforms on raisable legs or offshore constructions; Construction methods therefor placed by lowering the supporting construction to the bottom, e.g. with subsequent fixing thereto
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B63—SHIPS OR OTHER WATERBORNE VESSELS; RELATED EQUIPMENT
- B63B—SHIPS OR OTHER WATERBORNE VESSELS; EQUIPMENT FOR SHIPPING
- B63B35/00—Vessels or similar floating structures specially adapted for specific purposes and not otherwise provided for
- B63B35/44—Floating buildings, stores, drilling platforms, or workshops, e.g. carrying water-oil separating devices
-
- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02B—HYDRAULIC ENGINEERING
- E02B17/00—Artificial islands mounted on piles or like supports, e.g. platforms on raisable legs or offshore constructions; Construction methods therefor
- E02B17/02—Artificial islands mounted on piles or like supports, e.g. platforms on raisable legs or offshore constructions; Construction methods therefor placed by lowering the supporting construction to the bottom, e.g. with subsequent fixing thereto
- E02B17/021—Artificial islands mounted on piles or like supports, e.g. platforms on raisable legs or offshore constructions; Construction methods therefor placed by lowering the supporting construction to the bottom, e.g. with subsequent fixing thereto with relative movement between supporting construction and platform
-
- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02B—HYDRAULIC ENGINEERING
- E02B17/00—Artificial islands mounted on piles or like supports, e.g. platforms on raisable legs or offshore constructions; Construction methods therefor
- E02B17/04—Equipment specially adapted for raising, lowering, or immobilising the working platform relative to the supporting construction
- E02B17/08—Equipment specially adapted for raising, lowering, or immobilising the working platform relative to the supporting construction for raising or lowering
- E02B17/0836—Equipment specially adapted for raising, lowering, or immobilising the working platform relative to the supporting construction for raising or lowering with climbing jacks
- E02B17/0872—Equipment specially adapted for raising, lowering, or immobilising the working platform relative to the supporting construction for raising or lowering with climbing jacks with locking pins engaging holes or cam surfaces
Definitions
- the invention relates to a platform topside for an offshore platform and to a method for installing a platform topside for an offshore platform.
- Offshore platforms are artificial platforms in the ocean, which mostly serve to house technology and accommodations for personnel.
- the invention relates in particular to offshore platforms for collecting electrical energy from offshore wind turbines and its transfer to an onshore station in the rectified or unrectified state.
- Such offshore platforms are also called transformer platforms.
- the invention is also applicable to other offshore areas.
- Offshore platforms with a substructure made of a tubular steel frame are already known.
- the tubular steel frame is towed to the setup site on a barge using a tugboat. There, it is lowered to the ocean floor by means of floating cranes. Furthermore, piles are inserted into the corresponding bearings of the substructure using floating cranes and driven into the ocean floor. The piles are grouted with the substructure.
- a platform topside is transported to the setup site on a barge and legs are inserted in the corresponding bearings of the platform topside by means of floating cranes.
- the legs are inserted in the upper openings of the piles with their lower ends near the ocean floor and grouted with them.
- the underwater work must be inspected and executed by dive robots or divers.
- the object of the invention is to provide a platform topside for an offshore platform and a method suitable for installing a platform topside for an offshore platform, which reduces the effort for the erection of the offshore platform.
- the platform topside for an offshore platform includes:
- the platform topside according to the invention comprises a self-floating, superstructure with a stable floating position, which is preferably made in shipbuilding design from plates and profiles.
- the superstructure can be brought from the shore to the setup site at sea in a self-floating manner. Tugboats can be used for this. It is not required to provide the superstructure with an own drive.
- the use of barges and other transport means for the transport of the platform topside to the setup site is not needed.
- the width of the water line of the superstructure is designed such that taking on ballast water for the transit can be foregone.
- the platform topside can be installed on any substructure, which has connection points or respectively interfaces for a platform topside to be installed above the surface of the water or not far below the surface of the water.
- the means for mounting legs are arranged in projections of the platform topside and the projections as well as the means for mounting are arranged above the water line or not far below the water line.
- the cross-section of the superstructure is designed such that it lies in the area of the means for mounting the legs above the water line or not far below the water line. It is hereby achieved that the connection between the platform topside and the substructure can be performed above the surface of the water or not far below the surface of the water and thus within the visual range.
- the platform topside with the projections is placeable above the connection points of the substructure and the legs can then be lowered to the connection points.
- the means for the displacing of the legs are used, which make it possible to displace the legs in their longitudinal direction.
- the connection of the legs of the platform topside with the substructure can take place within visual range and under particularly beneficial conditions. Dive robots or divers are not required for this.
- the work can be done from the platform topside or from work rafts positioned next to the projections.
- the use of ship cranes for unloading the platform topside from a barge and placing the platform topside below the substructure and the insertion and lowering of the legs can be omitted.
- the superstructure has a stable floating position, i.e.
- the platform can be brought into a defined initial position, from which the legs can be easily lowered to the connection points of the substructure.
- the substructure can be used as an aid for the positioning of the platform topside.
- the means for displacing the legs are used in order to lift the platform topside to an installation height after the connection of the legs with the interfaces of the substructure. This height is dimensioned such that the water level does not reach the platform topside and the highest expected wave passes below the platform topside. In this position, the legs are fixed by means of the means for fixing.
- connection points of the substructure preferably protrude from the surface of the water by a maximum of 6 meters, more preferably by a maximum of 3 meters, most preferably by a maximum of 1.5 meters.
- connection points arranged below the surface of the water are preferably arranged within visual range below the surface of the water.
- the visual range is the area below the water line that can be seen by an adult person with normal vision with the unaided eye. In the case of an interface below the water line, the visual range can be extended by suitable measures.
- the design can be realized e.g. with markings in the form of rods or tubes, which are lead up from the substructure to above the water line and determine the position of the interface.
- connection points arranged below the water line preferably have a maximum distance of 6 meters from the surface of the water, more preferably a maximum of 3 meters from the surface of the water, most preferably a maximum of 1.5 meters from the surface of the water.
- the dimensioning of the substructure and the platform topside is based on a certain water level according to a water level analysis.
- This is preferably the MWL (mean water level) or LAT (lowest astronomical tide) or HAT (highest astronomical tide), or another defined water level from tidology.
- a suitable water level can be selected, on which the dimensioning of the substructure and the platform topside is based.
- the water level analysis provides the respective water levels for specified installation times.
- the means for mounting the legs in the upright arrangement or respectively upright position are designed such that they mount the legs in the most vertical alignment possible.
- the means for mounting the legs preferably mount the legs in the vertical alignment, if applicable with deviations (maximum 5°, preferably maximum 2°).
- the legs are mounted in the means for mounting and the platform topside equipped with the legs is self-floating with a stable floating position.
- the legs are thereby fixed in their position in the means for displacing by means of the means for fixing.
- the superstructure serves as a transport means for the legs, in order to float the superstructure together with the legs to the setup site. The legs do not need to be transported separately to the setup site at sea.
- the means for fixing the legs serve to fix the legs in a raised initial position during transit from the shore to the setup site at sea. Furthermore, they serve to fix the legs in the lowered position if the legs are connected with the connection points of the substructure.
- the structure has projections on both sides of a center part and/or two side parts with projections in the form of a bridge.
- the first variant has the advantage that the connection points of the legs with the substructure are visible and accessible from locations next to the superstructure. Moreover, the legs are located on the outer edge of the platform topside, which is advantageous for the statics of the offshore platform.
- the superstructure is designed in its cross-section like a catamaran, and the two projections are combined into a single bridge between the two side parts.
- the third variant is a combination with a center part and side parts on both sides of the center part as well as projections in the form of bridges connecting the center part and the side parts.
- the third variant has a cross-section like a trimaran.
- the center part contains one or more buoyancy cells and, in the case of the second variant, the side parts.
- the side parts and the center part can contain buoyancy cells.
- the second variant has a more stable floating position than the first.
- the means for mounting legs each have an upper leg bearing and a lower leg bearing arranged at a distance from it for mounting a leg. Stable means for mounting legs in vertical alignment are hereby achieved with relatively little structural effort.
- the upper leg bearings are integrated into the main deck of the superstructure and the lower leg bearings into a bottom wall of the projections. This design is constructive and especially beneficial from a production point of view.
- the means for displacing in the vertical direction are simultaneously the means for fixing the legs in vertical positions. Construction effort is hereby saved.
- known jacking systems designed as bolts in a pin-in-hole system or a strand jacking system can be used as combined means for displacing and fixing the legs. These systems can be partially retrofitted and used for other purposes after the installation of the platform topside. This applies in particular to hydraulic and other lifting components.
- the legs have a cone tapering downward on the bottom end and/or a ledge at a distance from the bottom end.
- the cone serves as an insertion aid during the connection of the legs with the substructure.
- the cone is preferably connected with a pile or a connection unit installed on the pile.
- the pile or respectively the connection unit is hollow-cylindrical and the cone is easily insertable into an upper opening of the pile or respectively of the connection units.
- the method according to the invention suitable for installing a platform topside comprises the following steps:
- the platform topside is equipped with the legs before being brought to the setup site.
- the legs are connected with piles or towers of a substructure above the surface of the water or not far below the surface of the water.
- the legs are connected in a form-fit manner with the piles or towers of a substructure.
- the substructure is used as a positioning aid of the platform topside during the positioning of the platform topside above the substructure.
- the means for displacing the legs are at least partially dismantled from the platform topside for other uses after the lowering of the legs and the later raising of the platform topside.
- a cable tower on the substructure is connected with the platform topside after the raising of the platform topside.
- the terms “above” and “below” refer to the arrangement of the offshore platform with the substructure below the platform topside with upright piles and vertically upright legs.
- FIG. 1 shows an offshore platform consisting of a substructure and a platform topside in a perspective view diagonally from above and from the side;
- FIG. 2 shows a substructure of the offshore platform with lowered piles in a perspective view diagonally from above and from the side;
- FIG. 3 shows the substructure in the same state in a side view
- FIG. 4 shows the substructure in a top view
- FIG. 5 shows a tower of the substructure with an inserted pile in a horizontal section
- FIG. 6 shows the tower with the inserted pile in a vertical section
- FIG. 7 shows a bottom bearing of the tower with the inserted pile in a vertical section
- FIG. 8 shows a clamping device of the tower with the inserted pile in a vertical section
- FIG. 9 shows the substructure with piles in the raised initial position in the floating state in a vertical section
- FIG. 10 shows the lowered substructure with piles driven into the ocean floor in a vertical section
- FIG. 11 shows the platform topside in a raised state on the legs in a perspective view diagonally from above and from the side;
- FIG. 12 shows the platform topside in the same position on the legs in a side view
- FIG. 13 shows the platform topside with the legs in the raised initial position in the floating position in a vertical section
- FIG. 14 shows a jacking system for displacing the legs with respect to the platform topside in a certain position of the leg in a side view
- FIG. 15 shows the same jacking system in a lower position of the leg with respect to FIG. 10 in a side view
- FIG. 16 shows an interface between a pile and a leg before the establishment of the connection in a side view
- FIG. 17 shows the same interface after the establishment of the connection in a side view
- FIG. 18 shows the same interface after the establishment of the connection in a vertical section
- FIG. 19 shows the same platform topside during connection of the legs with the piles of the substructure in a vertical section
- FIG. 20 shows the offshore platform after the raising of the platform topside with respect to the legs in a vertical section.
- an offshore platform 1 comprises a substructure 2 , which is deposited on the ocean floor 3 .
- the substructure 2 forms with piles 4 the foundation structure of the offshore platform 1 .
- the piles 4 also called “nails”, are driven into the ocean floor 3 , in order to establish a pile foundation and to anchor the substructure 2 on the ocean floor 3 .
- the piles 4 serve to transfer loads from the platform topside 5 .
- the piles 4 are preferably circular-cylindrical. They are preferably hollow-cylindrical.
- the platform topside 5 is a supporting structure, which is arranged in the area above the surface of the water 6 and outside the sphere of influence of the sea.
- the platform topside 5 is supported on the foundation structure via legs 7 .
- the legs 7 are each incorporated on the top into the structure of the platform topside 5 and connected on the bottom with a pile 4 .
- the legs 7 are preferably circular-cylindrical. They are preferably hollow-cylindrical.
- the substructure 2 has a structure 8 , which comprises a horizontal, rectangular base frame 9 .
- the base frame 9 has four straight-line frame parts 10 .
- each tower 11 protrude upwards from frame 9 .
- the towers 11 are flush with the bottom side of the base frame 9 .
- the towers 11 are hollow bodies. In the example, they have an octagonal cross-section.
- Each tower 11 is located on one corner of the base frame 9 and simultaneously forms a connection element between two neighboring frame parts 10 .
- each of the frame parts 10 carry support elements 12 on the ends, which support the towers 11 laterally.
- each of the hollow-cylindrical towers 11 have a circular, bottom opening 13 and, on the top end, a circular, upper opening 14 for the passage of a pile 4 .
- each tower 11 comprises a sleeve-like, bottom bearing 15 connecting to the bottom opening 13 and a sleeve-like, upper bearing 16 connecting to the upper opening 14 .
- a pressure seal 17 for sealing the bottom bearing 16 from the pile 4 is present in the bottom bearing 15 .
- the bottom structure 8 made up of the base frame 9 and the towers 11 is a shipbuilding steel construction made of plates and profiles. The plates and profiles are welded together.
- each tank 18 there are several separate tanks 18 located inside the bottom structure 8 .
- a separate tank 18 is arranged in each frame part 8 .
- the tanks 18 are each connected with means for flooding 19 and means for pumping out 20 , via which each tank can be flooded and pumped out separately.
- the means for flooding 19 are suitable valves.
- the means for pumping out 20 are removable pumps with associated lines.
- a hollow area sealed laterally and on the bottom is present in each tower 11 around the pile 4 when the pile 4 is held in the lower and upper bearing 15 , 16 .
- the hollow area forms another tank 21 .
- This is in turn separately floodable and pumpable via other separate means for flooding 22 in the form of valves and other means for pumping out 23 in the form of pumps and associated lines.
- means for the fixation and braking 24 of a pile 4 in a vertical position is present in each tower.
- the device that holds the piles in position in a force-fit or form-fit manner can hereby be mechanical or hydraulic.
- they are clamping jaws 25 , 26 , which rest on a horizontal bearing 27 and enclose a pile 4 on different sides.
- the piles 4 can be drained in a controlled manner by releasing the brake device.
- the tanks 18 , 21 are dimensioned such that they ensure the buoyancy for the floating of the substructure 2 including the piles 4 in the empty state.
- the substructure 2 is self-floating and has a stable floating position. It does not have its own drive.
- a control stand 28 is present on the top of at least one tower 11 .
- the means for flooding 19 are connected with means for controlling 29 the means for flooding in the control stand 28 .
- measurement and display devices 30 , 31 for capturing and displaying the trim of the structure 8 are present in the control stand.
- the substructure comprises a vertical cable tower 32 , which is made of a bundle of individual pipes 33 .
- the cable tower 32 is arranged outside of the frame 9 . It is connected with a tower 11 laterally via braces 34 .
- the base frame 9 in the neighboring corner is provided with a prismatic buoyancy body 35 .
- the buoyancy body 35 stabilizes the base frame 9 at the same time.
- the height of the towers 11 is adjusted to the water level at the setup site so that the upper ends of the towers 11 protrude out of the water at the time of the installation of the offshore platform 1 .
- the length of the frame is 47.5 meters and its width on the main deck is 41.5 meters.
- the substructure is intended for a setup site with a lowest astronomical tide (LAT) of 24 meters.
- the height of the towers 11 is 25.5 meters so that the towers 11 at the setup site protrude out of the water at certain times under normal sea states, for example in the case of moderate swell conditions (sea state 4 ).
- the cable tower 32 is measured such that it protrudes up to the platform topside 5 .
- its length is 40 meters.
- the piles 4 are hollow and cylindrical. On the bottom, they are preferably closed during the transport and are opened on the bottom for driving. According to FIG. 16 through 18 , the piles 4 have an opening 35 on the top, into which a leg 5 can be inserted.
- the substructure 2 is produced in a construction dock of a shipyard.
- the equipment including the means for flooding and pumping out ( 19 , 20 , 21 , 22 ) and optionally the piles 4 are installed in the substructure 2 .
- the piles 4 can be inserted into the lower and upper bearings 15 , 16 of the towers 11 in the construction dock by means of a (portal) crane and fixed therein in an initial position by means of the clamping jaws 25 , 26 , in which they do not protrude on the bottom from the base frame 9 .
- the cable tower 32 can be installed in the construction dock.
- the substructure 2 is floated in the construction dock and moved to the finishing pier for final finishing and testing. After structural approval, the transit of the substructure 2 to the installation site takes place in the towing convoy with corresponding temporary firing. The floating state is shown in FIG. 9 .
- the ocean floor 3 is prepared before installing the substructure 2 , if its irregularities are too significant. For this, an even surface is created on the ocean floor 3 , which meets the defined tolerances for the installation of the offshore platform 2 and a suitable subsurface for the substructure 2 is formed.
- the substructure 2 is positioned above the setup site by sea-going tugboats.
- the tugboats can automatically be held in a predetermined position by means of a dynamic positioning system.
- the DP2 system can be used, for example.
- the flooding of the tanks 18 , 21 takes place manually via the control stand 28 of the substructure depending on the trim displayed by the display device 31 .
- the tanks 18 , 21 can be flooded using a remote control.
- the trim is monitored by the measurement devices 30 on the substructure 2 and, if necessary, the measurement results are transferred to a location outside the substructure 2 , from which the flooding can be controlled remotely.
- the piles 4 are lowered using gravity. For this, the clamping jaws 25 , 26 are controlled from the control stand 28 . If necessary, the lowering of the piles 4 is braked by means of the clamping jaws 25 , 26 . Under their own weight, the piles 4 are only partially driven into the ocean substrate 3 . They are additionally driven into the ocean substrate 3 with pile hammers, which are positioned on the top of the piles.
- the mounting of the piles 4 in the towers 11 serves to guide the piles 4 during the driving process.
- the piles 4 are driven into the ocean substrate 3 until their top end is flush with the top end of the towers 11 . This is shown in FIG. 10 .
- the piles 4 are then connected in a form-fit manner with the substructure 2 .
- the form-fit connection preferably takes place through grouting.
- liquid concrete or artificial resin or another hardening, groutable mass is injected into a gap 36 between the pile 4 and the lower bearing 16 .
- the lower bearing 15 is also provided with an upper seal 37 , which, together with the pressure seal 17 , prevents the grouting medium 38 from escaping out of the gap 36 .
- the tower 11 is also permanently sealed on the bottom.
- the upper openings 35 of the piles 4 are thus located as interfaces for receiving the legs 7 for carrying the platform topside 5 at the time of installation above the surface of the water 6 .
- the platform topside 5 has a superstructure 39 , which has a box-shaped center part 40 and projections 42 , 43 above the water line 41 , i.e. above the floating water line of the platform topside 5 .
- the side walls 44 , 45 of the superstructure 39 are thus inserted below the projections 42 , 43 .
- the structure 39 thus has a symmetrical T-shaped cross-section (see FIG. 12 ), wherein the center part 40 forms the vertical T-post and the projections 42 , 43 form the laterally protruding beam parts of the horizontal T-beam.
- the center part 40 is partitioned off from the projections 42 , 43 . It has a double floor 46 on the bottom and it is closed by a main deck 47 on the top. It has one or more buoyancy cells 48 , which are separated from each other by transverse bulkheads.
- Means for mounting 49 the legs 7 are located in the lateral projections 42 , 43 .
- For each leg 7 there is a lower leg bearing 50 and an upper leg bearing 51 , which align with each other.
- the lower leg bearing 50 is arranged in a bottom wall 52 of the projection 42 , 43 and the upper leg bearing 51 is arranged in a cover wall 53 of the projection 42 , 43 , which is a lateral strip of the main deck 47 of the platform topside 5 .
- the bottom wall 52 and the cover wall 53 of the projections 42 , 43 have reinforcements on the lower and upper leg bearings 50 , 51 .
- the lower and upper leg bearings 50 , 51 are circular through holes through the bottom wall 52 and the cover wall 53 at the reinforced positions.
- the superstructure 39 is also mainly symmetrical in the longitudinal direction.
- Personnel rooms or respectively service rooms can be located in the superstructure 39 .
- a jacking system 54 which is shown separately in FIGS. 14 and 15 , is present above each upper leg bearing 51 .
- the jacking system 54 has a fixed rest 55 permanently fixed on deck. This is hereby a plate with a vertical through hole 56 , through which a leg 7 can be inserted.
- the fixed rest 55 has a horizontal hole 57 , which extends from an outside of the fixed rest 55 up to the inner circumference of the vertical through hole 56 .
- the jacking system 54 comprises a displaceable rest 58 .
- This is hereby also a plate with a vertical through hole 59 , which receives a leg 7 .
- the fixed rest 55 has a horizontal hole 60 , which extends from an outside of the displaceable rest 58 up to the inner circumference of the vertical through hole 59 .
- the jacking system 54 has hydraulic cylinders 61 , which are fixed on the bottom on the fixed rest 55 and on the top on the displaceable rest 58 .
- the displaceable rest 58 is vertically liftable or respectively lowerable by means of the hydraulic cylinder 61 .
- the hydraulic cylinders 61 include a hydraulic controller and a pressurized supply with a hydraulic medium.
- the legs 7 are each provided with a series of horizontal blind holes 62 .
- the leg 7 is locked to the platform topside 5 by inserting a bolt 63 into the horizontal hole 57 of the fixed rest 55 and into a horizontal blind hole 62 of the leg 7 so that it is not displaceable in the axial direction.
- the jacking system 54 is a pin in hole system. Alternatively, a strand jacking system can be provided.
- the buoyancy cells 48 are measured such that the superstructure 39 is self-floating when the legs 7 are mounted in the means for mounting 49 the legs and fixed by means of the jacking systems 54 .
- the water line 41 is thereby located below the projections 42 , 43 .
- the platform topside 5 is designed such that it has a stable floating position when the legs 7 are inserted into the lower and upper leg bearings 50 , 51 and do not protrude beyond the projections 42 , 43 on the bottom.
- the width of the water line 41 of the superstructure 39 is designed such that the taking on of ballast during the floating of the superstructure 39 can be foregone.
- the weight distribution of the platform topside 5 is approximately homogeneous. It is thus not necessary to use trim tanks to hold the platform topside 5 in a stable trim. But trim tanks can be used, if needed.
- the platform topside 5 is self-floating and does not have its own drive. Thus, transport on a barge is not necessary.
- the platform topside has a length of 73 m, a width on the main deck of 49.5 m, on the bottom a width of 31.5 m and a height from the lower edge to the deck of 26.5 m.
- each of the legs 7 has a ledge 64 , under which its outer diameter is smaller than the inner diameter of the piles 4 by a certain amount.
- the legs 7 have a frustoconical section 65 .
- the leg 7 With the frustoconical section 65 , the leg 7 is insertable into the upper opening 35 of a pile 4 , until the ledge 64 rests on the upper edge of the pile 4 .
- a hollow-cylindrical gap 65 remains between the section with the reduced diameter of the leg and the pile.
- the length of the legs 7 is approximately 45 m.
- the platform topside 5 can be built in a construction dock of a shipyard.
- the legs 7 are preferably inserted into the lower and upper leg bearings 50 , 51 by means of a (portal) crane and secured in the lower rest 55 by means of bolts 63 .
- the platform topside 5 is then floated at the setup site and hauled to the shipyard pier for final rig up and for testing.
- the installation of the removable components of the jacking system 54 can then take place on the main deck 47 .
- the platform topside 5 is then floated to the installation site in the towing convoy with corresponding temporary firing.
- the platform topside 5 is floated into position above the substructure 2 and positioned on the substructure 2 with the help of tugboats at the defined point in time by positioners or respectively fenders in accordance with water level analysis.
- the substructure 2 can hereby be used as an insertion and positioning aid.
- the legs 7 are then located in the projections 42 , 43 exactly above the assigned piles 4 of the substructure 2 .
- the legs 7 are then lowered onto the piles 4 by means of the jacking systems 54 so that the legs 7 engage with the lower ends into the upper openings 35 of the piles 4 and fit with the ledges 64 .
- the lowering takes place by means of the jacking systems 54 such that the hydraulic cylinders 61 are moved apart and the horizontal hole 60 of the displaceable rest 58 is aligned with a blind hole 62 of a leg 7 .
- a bolt 63 is then inserted into the horizontal hole 60 and the blind hole 62 and the bolt 63 is pulled out of the fixed rest 55 .
- the hydraulic cylinders 61 are then moved together whereby the legs 7 are lowered. They were lowered until a blind hole 62 of the leg 7 is aligned with the horizontal hole 57 of the fixed rest 55 . Each of the legs 7 is then secured by means of a bolt, which is inserted into the horizontal hole 57 of the fixed rest 55 and the blind hole 62 of the leg 7 . The bolt 63 is then pulled out of the displaceable rest 58 and the processes described above are repeated until the legs 7 are in their final position.
- the legs 7 When the legs 7 engage in the piles 4 according to FIG. 18 , they are connected in a form-fit manner with the piles. For this, they are preferably grouted with the piles in that a grouting agent 67 is inserted into the gap 66 .
- the above work is comparatively easy to perform since the interface or respectively connection point between the legs 7 and the piles 4 is located above the water surface 6 or not far below the surface of the water 6 .
- the platform topside 5 is raised to the predetermined installation height.
- the installation height is selected such that the highest possible wave (“century wave”) to be expected according to the water level analysis still passes below the platform topside.
- the installation height is 161 m above LAT.
- the raising of the platform topside 5 is performed by means of the jacking systems 54 . They are operated in the manner described above, wherein the platform topside 5 is raised by pulling the hydraulic cylinders 61 together. Once the platform topside 5 has reached the installation height, the legs 7 secured in the end position by inserting bolts 63 into the horizontal hole 57 of the fixed rest 55 and in blind holes 62 of the legs 7 . An elastically mounted bolt connection can be used for this.
- the finished offshore platform 1 is shown in FIG. 1 .
- the cable tower 32 reaches up to a lateral projection 42 .
- a bridge 68 is additionally attached, via which sea cables can be guided into the platform topside 5 and the installation work is facilitated.
- any dependent claim which follows should be taken as alternatively written in a multiple dependent form from all prior claims which possess all antecedents referenced in such dependent claim if such multiple dependent format is an accepted format within the jurisdiction (e.g. each claim depending directly from claim 1 should be alternatively taken as depending from all previous claims).
- each claim depending directly from claim 1 should be alternatively taken as depending from all previous claims.
- the following dependent claims should each be also taken as alternatively written in each singly dependent claim format which creates a dependency from a prior antecedent-possessing claim other than the specific claim listed in such dependent claim below.
Landscapes
- Engineering & Computer Science (AREA)
- General Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- Civil Engineering (AREA)
- Structural Engineering (AREA)
- Architecture (AREA)
- Chemical & Material Sciences (AREA)
- Combustion & Propulsion (AREA)
- Ocean & Marine Engineering (AREA)
- Foundations (AREA)
- Earth Drilling (AREA)
Abstract
A platform topside for an offshore platform including a self-floating superstructure with a stable floating position, projections on the superstructure, means for mounting legs in an upright arrangement in the projections, wherein the projections and the means for mounting legs are arranged above the water line or not far below the water line, means for displacing the legs in the longitudinal direction of the legs in the means for mounting and means for fixing the legs in their positions in the means for mounting.
Description
- Not applicable
- Not applicable
- The invention relates to a platform topside for an offshore platform and to a method for installing a platform topside for an offshore platform.
- Offshore platforms are artificial platforms in the ocean, which mostly serve to house technology and accommodations for personnel. The invention relates in particular to offshore platforms for collecting electrical energy from offshore wind turbines and its transfer to an onshore station in the rectified or unrectified state. Such offshore platforms are also called transformer platforms. The invention is also applicable to other offshore areas.
- Offshore platforms with a substructure made of a tubular steel frame are already known. The tubular steel frame is towed to the setup site on a barge using a tugboat. There, it is lowered to the ocean floor by means of floating cranes. Furthermore, piles are inserted into the corresponding bearings of the substructure using floating cranes and driven into the ocean floor. The piles are grouted with the substructure.
- Furthermore, a platform topside is transported to the setup site on a barge and legs are inserted in the corresponding bearings of the platform topside by means of floating cranes. The legs are inserted in the upper openings of the piles with their lower ends near the ocean floor and grouted with them. The underwater work must be inspected and executed by dive robots or divers.
- The use of self-floating platform topsides that are towed to the setup site with inserted legs is also already known. There, the legs are connected with the piles in the described manner.
- The installation of the known offshore platforms is complex.
- Based on this, the object of the invention is to provide a platform topside for an offshore platform and a method suitable for installing a platform topside for an offshore platform, which reduces the effort for the erection of the offshore platform.
- The platform topside for an offshore platform according to the invention includes:
-
- a self-floating, superstructure with stable floating position,
- projections on the superstructure,
- means for mounting legs in an upright arrangement in the projections,
- wherein the projections and the means for mounting legs are arranged above the water line or not far below the water line,
- means for displacing the legs in the longitudinal direction of the legs in the means for mounting and
- means for fixing the legs in their positions in the means for mounting.
- The platform topside according to the invention comprises a self-floating, superstructure with a stable floating position, which is preferably made in shipbuilding design from plates and profiles. The superstructure can be brought from the shore to the setup site at sea in a self-floating manner. Tugboats can be used for this. It is not required to provide the superstructure with an own drive. The use of barges and other transport means for the transport of the platform topside to the setup site is not needed. Preferably, the width of the water line of the superstructure is designed such that taking on ballast water for the transit can be foregone. At the setup site, the platform topside can be installed on any substructure, which has connection points or respectively interfaces for a platform topside to be installed above the surface of the water or not far below the surface of the water. For this, the means for mounting legs are arranged in projections of the platform topside and the projections as well as the means for mounting are arranged above the water line or not far below the water line. The cross-section of the superstructure is designed such that it lies in the area of the means for mounting the legs above the water line or not far below the water line. It is hereby achieved that the connection between the platform topside and the substructure can be performed above the surface of the water or not far below the surface of the water and thus within the visual range. For this, the platform topside with the projections is placeable above the connection points of the substructure and the legs can then be lowered to the connection points. For this, the means for the displacing of the legs are used, which make it possible to displace the legs in their longitudinal direction. The connection of the legs of the platform topside with the substructure can take place within visual range and under particularly beneficial conditions. Dive robots or divers are not required for this. The work can be done from the platform topside or from work rafts positioned next to the projections. The use of ship cranes for unloading the platform topside from a barge and placing the platform topside below the substructure and the insertion and lowering of the legs can be omitted. The superstructure has a stable floating position, i.e. it automatically erects itself from the laterally inclined position as long as the incline does not exceed a maximum value. As a result, the platform can be brought into a defined initial position, from which the legs can be easily lowered to the connection points of the substructure. The substructure can be used as an aid for the positioning of the platform topside. The means for displacing the legs are used in order to lift the platform topside to an installation height after the connection of the legs with the interfaces of the substructure. This height is dimensioned such that the water level does not reach the platform topside and the highest expected wave passes below the platform topside. In this position, the legs are fixed by means of the means for fixing.
- The connection points of the substructure preferably protrude from the surface of the water by a maximum of 6 meters, more preferably by a maximum of 3 meters, most preferably by a maximum of 1.5 meters.
- Connection points arranged below the surface of the water are preferably arranged within visual range below the surface of the water. The visual range is the area below the water line that can be seen by an adult person with normal vision with the unaided eye. In the case of an interface below the water line, the visual range can be extended by suitable measures.
- This takes place through elements attached to the substructure that are visible above the water line and determine the position of the interface. The design can be realized e.g. with markings in the form of rods or tubes, which are lead up from the substructure to above the water line and determine the position of the interface.
- The connection points arranged below the water line preferably have a maximum distance of 6 meters from the surface of the water, more preferably a maximum of 3 meters from the surface of the water, most preferably a maximum of 1.5 meters from the surface of the water.
- The dimensioning of the substructure and the platform topside is based on a certain water level according to a water level analysis. This is preferably the MWL (mean water level) or LAT (lowest astronomical tide) or HAT (highest astronomical tide), or another defined water level from tidology. Depending on the time window needed for the connection of the substructure and the platform topside, a suitable water level can be selected, on which the dimensioning of the substructure and the platform topside is based. The water level analysis provides the respective water levels for specified installation times.
- The means for mounting the legs in the upright arrangement or respectively upright position are designed such that they mount the legs in the most vertical alignment possible. The means for mounting the legs preferably mount the legs in the vertical alignment, if applicable with deviations (maximum 5°, preferably maximum 2°).
- In accordance with an advantageous embodiment of the invention, the legs are mounted in the means for mounting and the platform topside equipped with the legs is self-floating with a stable floating position. The legs are thereby fixed in their position in the means for displacing by means of the means for fixing. In this embodiment, the superstructure serves as a transport means for the legs, in order to float the superstructure together with the legs to the setup site. The legs do not need to be transported separately to the setup site at sea.
- The means for fixing the legs serve to fix the legs in a raised initial position during transit from the shore to the setup site at sea. Furthermore, they serve to fix the legs in the lowered position if the legs are connected with the connection points of the substructure.
- According to a preferred embodiment, the structure has projections on both sides of a center part and/or two side parts with projections in the form of a bridge. The first variant has the advantage that the connection points of the legs with the substructure are visible and accessible from locations next to the superstructure. Moreover, the legs are located on the outer edge of the platform topside, which is advantageous for the statics of the offshore platform. In the case of the second variant, the superstructure is designed in its cross-section like a catamaran, and the two projections are combined into a single bridge between the two side parts. The third variant is a combination with a center part and side parts on both sides of the center part as well as projections in the form of bridges connecting the center part and the side parts. The third variant has a cross-section like a trimaran. In the case of the first variant, the center part contains one or more buoyancy cells and, in the case of the second variant, the side parts. In the case of the third variant, the side parts and the center part can contain buoyancy cells. The second variant has a more stable floating position than the first.
- In the case of a further embodiment, the means for mounting legs each have an upper leg bearing and a lower leg bearing arranged at a distance from it for mounting a leg. Stable means for mounting legs in vertical alignment are hereby achieved with relatively little structural effort.
- According to another embodiment, the upper leg bearings are integrated into the main deck of the superstructure and the lower leg bearings into a bottom wall of the projections. This design is constructive and especially beneficial from a production point of view.
- According to another embodiment, the means for displacing in the vertical direction are simultaneously the means for fixing the legs in vertical positions. Construction effort is hereby saved. For example, known jacking systems designed as bolts in a pin-in-hole system or a strand jacking system can be used as combined means for displacing and fixing the legs. These systems can be partially retrofitted and used for other purposes after the installation of the platform topside. This applies in particular to hydraulic and other lifting components.
- According to another embodiment, the legs have a cone tapering downward on the bottom end and/or a ledge at a distance from the bottom end. The cone serves as an insertion aid during the connection of the legs with the substructure. The cone is preferably connected with a pile or a connection unit installed on the pile. The pile or respectively the connection unit is hollow-cylindrical and the cone is easily insertable into an upper opening of the pile or respectively of the connection units. Once the legs are completely inserted into the pile or the connection unit, the ledge is supported on the upper edge of the piles or the connection unit.
- The method according to the invention suitable for installing a platform topside comprises the following steps:
-
- constructing the platform,
- bringing the platform to the setup site in a self-floating manner,
- positioning the platform above a substructure,
- lowering the legs of the platform and connecting them with the substructure above the surface of the water or not far below the surface of the water,
- raising the platform topside by means of the legs and
- fastening the platform on the legs.
- According to one embodiment of the method, the platform topside is equipped with the legs before being brought to the setup site.
- According to another embodiment of the method, the legs are connected with piles or towers of a substructure above the surface of the water or not far below the surface of the water.
- According to another embodiment, the legs are connected in a form-fit manner with the piles or towers of a substructure.
- According to another embodiment, the substructure is used as a positioning aid of the platform topside during the positioning of the platform topside above the substructure.
- According to another embodiment, the means for displacing the legs are at least partially dismantled from the platform topside for other uses after the lowering of the legs and the later raising of the platform topside.
- According to another embodiment, a cable tower on the substructure is connected with the platform topside after the raising of the platform topside.
- In this patent application, the terms “above” and “below” refer to the arrangement of the offshore platform with the substructure below the platform topside with upright piles and vertically upright legs.
- The invention is explained in greater detail below based on the included drawings of an exemplary embodiment.
- In the drawings:
-
FIG. 1 shows an offshore platform consisting of a substructure and a platform topside in a perspective view diagonally from above and from the side; -
FIG. 2 shows a substructure of the offshore platform with lowered piles in a perspective view diagonally from above and from the side; -
FIG. 3 shows the substructure in the same state in a side view; -
FIG. 4 shows the substructure in a top view; -
FIG. 5 shows a tower of the substructure with an inserted pile in a horizontal section; -
FIG. 6 shows the tower with the inserted pile in a vertical section; -
FIG. 7 shows a bottom bearing of the tower with the inserted pile in a vertical section; -
FIG. 8 shows a clamping device of the tower with the inserted pile in a vertical section; -
FIG. 9 shows the substructure with piles in the raised initial position in the floating state in a vertical section; -
FIG. 10 shows the lowered substructure with piles driven into the ocean floor in a vertical section; -
FIG. 11 shows the platform topside in a raised state on the legs in a perspective view diagonally from above and from the side; -
FIG. 12 shows the platform topside in the same position on the legs in a side view; -
FIG. 13 shows the platform topside with the legs in the raised initial position in the floating position in a vertical section; -
FIG. 14 shows a jacking system for displacing the legs with respect to the platform topside in a certain position of the leg in a side view; -
FIG. 15 shows the same jacking system in a lower position of the leg with respect toFIG. 10 in a side view; -
FIG. 16 shows an interface between a pile and a leg before the establishment of the connection in a side view; -
FIG. 17 shows the same interface after the establishment of the connection in a side view; -
FIG. 18 shows the same interface after the establishment of the connection in a vertical section; -
FIG. 19 shows the same platform topside during connection of the legs with the piles of the substructure in a vertical section; -
FIG. 20 shows the offshore platform after the raising of the platform topside with respect to the legs in a vertical section. - While this invention may be embodied in many different forms, there are described in detail herein a specific preferred embodiment of the invention. This description is an exemplification of the principles of the invention and is not intended to limit the invention to the particular embodiment illustrated.
- According to
FIGS. 1 and 20 , anoffshore platform 1 comprises asubstructure 2, which is deposited on theocean floor 3. Thesubstructure 2 forms withpiles 4 the foundation structure of theoffshore platform 1. Thepiles 4, also called “nails”, are driven into theocean floor 3, in order to establish a pile foundation and to anchor thesubstructure 2 on theocean floor 3. Thepiles 4 serve to transfer loads from theplatform topside 5. Thepiles 4 are preferably circular-cylindrical. They are preferably hollow-cylindrical. - The
platform topside 5 is a supporting structure, which is arranged in the area above the surface of thewater 6 and outside the sphere of influence of the sea. - The
platform topside 5 is supported on the foundation structure vialegs 7. Thelegs 7 are each incorporated on the top into the structure of theplatform topside 5 and connected on the bottom with apile 4. Thelegs 7 are preferably circular-cylindrical. They are preferably hollow-cylindrical. - According to
FIG. 2 through 4 , thesubstructure 2 has astructure 8, which comprises a horizontal,rectangular base frame 9. Thebase frame 9 has four straight-line frame parts 10. - Four
towers 11 protrude upwards fromframe 9. On the bottom, thetowers 11 are flush with the bottom side of thebase frame 9. Thetowers 11 are hollow bodies. In the example, they have an octagonal cross-section. Eachtower 11 is located on one corner of thebase frame 9 and simultaneously forms a connection element between two neighboringframe parts 10. On the top, each of theframe parts 10 carrysupport elements 12 on the ends, which support thetowers 11 laterally. - On the bottom end, each of the hollow-
cylindrical towers 11 have a circular,bottom opening 13 and, on the top end, a circular,upper opening 14 for the passage of apile 4. - According to
FIGS. 5 and 6 , eachtower 11 comprises a sleeve-like,bottom bearing 15 connecting to thebottom opening 13 and a sleeve-like,upper bearing 16 connecting to theupper opening 14. Apressure seal 17 for sealing the bottom bearing 16 from thepile 4 is present in thebottom bearing 15. - The
bottom structure 8 made up of thebase frame 9 and thetowers 11 is a shipbuilding steel construction made of plates and profiles. The plates and profiles are welded together. - There are several
separate tanks 18 located inside thebottom structure 8. In the example, aseparate tank 18 is arranged in eachframe part 8. Thetanks 18 are each connected with means forflooding 19 and means for pumping out 20, via which each tank can be flooded and pumped out separately. The means forflooding 19 are suitable valves. The means for pumping out 20 are removable pumps with associated lines. - According to
FIGS. 5 and 6 , a hollow area sealed laterally and on the bottom is present in eachtower 11 around thepile 4 when thepile 4 is held in the lower andupper bearing tank 21. This is in turn separately floodable and pumpable via other separate means for flooding 22 in the form of valves and other means for pumping out 23 in the form of pumps and associated lines. - Furthermore, according to
FIGS. 6 and 8 , means for the fixation andbraking 24 of apile 4 in a vertical position is present in each tower. The device that holds the piles in position in a force-fit or form-fit manner can hereby be mechanical or hydraulic. According toFIG. 8 , they are clampingjaws pile 4 on different sides. Through the tightening of the clampingjaws pile 4 is fixable so that it is not displaced downwards with respect to the tower due to its own weight. Thepiles 4 can be drained in a controlled manner by releasing the brake device. - The
tanks substructure 2 including thepiles 4 in the empty state. Thesubstructure 2 is self-floating and has a stable floating position. It does not have its own drive. - According to
FIG. 2 , acontrol stand 28 is present on the top of at least onetower 11. The means forflooding 19 are connected with means for controlling 29 the means for flooding in thecontrol stand 28. - Furthermore, measurement and display devices 30, 31 for capturing and displaying the trim of the
structure 8 are present in the control stand. - Moreover, the substructure comprises a
vertical cable tower 32, which is made of a bundle of individual pipes 33. Thecable tower 32 is arranged outside of theframe 9. It is connected with atower 11 laterally via braces 34. - In order to compensate for the weight of the
cable tower 32, thebase frame 9 in the neighboring corner is provided with aprismatic buoyancy body 35. Thebuoyancy body 35 stabilizes thebase frame 9 at the same time. - The height of the
towers 11 is adjusted to the water level at the setup site so that the upper ends of thetowers 11 protrude out of the water at the time of the installation of theoffshore platform 1. - In one example, the length of the frame is 47.5 meters and its width on the main deck is 41.5 meters. The substructure is intended for a setup site with a lowest astronomical tide (LAT) of 24 meters. The height of the
towers 11 is 25.5 meters so that thetowers 11 at the setup site protrude out of the water at certain times under normal sea states, for example in the case of moderate swell conditions (sea state 4). - The
cable tower 32 is measured such that it protrudes up to theplatform topside 5. In the example, its length is 40 meters. - The
piles 4 are hollow and cylindrical. On the bottom, they are preferably closed during the transport and are opened on the bottom for driving. According toFIG. 16 through 18 , thepiles 4 have anopening 35 on the top, into which aleg 5 can be inserted. - The
substructure 2 is produced in a construction dock of a shipyard. - During the construction phase, the equipment including the means for flooding and pumping out (19, 20, 21, 22) and optionally the
piles 4 are installed in thesubstructure 2. Thepiles 4 can be inserted into the lower andupper bearings towers 11 in the construction dock by means of a (portal) crane and fixed therein in an initial position by means of the clampingjaws base frame 9. - Optionally, the
cable tower 32 can be installed in the construction dock. - After complete assembly of all components, the
substructure 2 is floated in the construction dock and moved to the finishing pier for final finishing and testing. After structural approval, the transit of thesubstructure 2 to the installation site takes place in the towing convoy with corresponding temporary firing. The floating state is shown inFIG. 9 . - If necessary, the
ocean floor 3 is prepared before installing thesubstructure 2, if its irregularities are too significant. For this, an even surface is created on theocean floor 3, which meets the defined tolerances for the installation of theoffshore platform 2 and a suitable subsurface for thesubstructure 2 is formed. - The
substructure 2 is positioned above the setup site by sea-going tugboats. At the setup site, the tugboats can automatically be held in a predetermined position by means of a dynamic positioning system. The DP2 system can be used, for example. - The flooding of the
tanks - If necessary, the
tanks substructure 2 and, if necessary, the measurement results are transferred to a location outside thesubstructure 2, from which the flooding can be controlled remotely. - Once the
substructure 2 is resting on the ocean floor, thepiles 4 are lowered using gravity. For this, the clampingjaws control stand 28. If necessary, the lowering of thepiles 4 is braked by means of the clampingjaws piles 4 are only partially driven into theocean substrate 3. They are additionally driven into theocean substrate 3 with pile hammers, which are positioned on the top of the piles. - The mounting of the
piles 4 in thetowers 11 serves to guide thepiles 4 during the driving process. Thepiles 4 are driven into theocean substrate 3 until their top end is flush with the top end of thetowers 11. This is shown inFIG. 10 . - The
piles 4 are then connected in a form-fit manner with thesubstructure 2. The form-fit connection preferably takes place through grouting. For this, liquid concrete or artificial resin or another hardening, groutable mass is injected into agap 36 between thepile 4 and thelower bearing 16. Preferably, thelower bearing 15 is also provided with anupper seal 37, which, together with thepressure seal 17, prevents the grouting medium 38 from escaping out of thegap 36. Through the grouting, thetower 11 is also permanently sealed on the bottom. - The
upper openings 35 of thepiles 4 are thus located as interfaces for receiving thelegs 7 for carrying theplatform topside 5 at the time of installation above the surface of thewater 6. - According to
FIGS. 11 and 12 , theplatform topside 5 has asuperstructure 39, which has a box-shapedcenter part 40 andprojections water line 41, i.e. above the floating water line of theplatform topside 5. Theside walls superstructure 39 are thus inserted below theprojections structure 39 thus has a symmetrical T-shaped cross-section (seeFIG. 12 ), wherein thecenter part 40 forms the vertical T-post and theprojections - According to
FIG. 13 , thecenter part 40 is partitioned off from theprojections double floor 46 on the bottom and it is closed by amain deck 47 on the top. It has one ormore buoyancy cells 48, which are separated from each other by transverse bulkheads. - Means for mounting 49 the
legs 7 are located in thelateral projections leg 7, there is alower leg bearing 50 and anupper leg bearing 51, which align with each other. Thelower leg bearing 50 is arranged in abottom wall 52 of theprojection upper leg bearing 51 is arranged in acover wall 53 of theprojection main deck 47 of theplatform topside 5. Thebottom wall 52 and thecover wall 53 of theprojections upper leg bearings upper leg bearings bottom wall 52 and thecover wall 53 at the reinforced positions. - The
superstructure 39 is also mainly symmetrical in the longitudinal direction. - Personnel rooms or respectively service rooms can be located in the
superstructure 39. - A jacking
system 54, which is shown separately inFIGS. 14 and 15 , is present above eachupper leg bearing 51. The jackingsystem 54 has a fixedrest 55 permanently fixed on deck. This is hereby a plate with a vertical through hole 56, through which aleg 7 can be inserted. Furthermore, the fixedrest 55 has ahorizontal hole 57, which extends from an outside of the fixedrest 55 up to the inner circumference of the vertical through hole 56. - According to
FIGS. 14 and 15 , the jackingsystem 54 comprises adisplaceable rest 58. This is hereby also a plate with a vertical throughhole 59, which receives aleg 7. Furthermore, the fixedrest 55 has a horizontal hole 60, which extends from an outside of thedisplaceable rest 58 up to the inner circumference of the vertical throughhole 59. - Furthermore, the jacking
system 54 hashydraulic cylinders 61, which are fixed on the bottom on the fixedrest 55 and on the top on thedisplaceable rest 58. Thedisplaceable rest 58 is vertically liftable or respectively lowerable by means of thehydraulic cylinder 61. It goes without saying that thehydraulic cylinders 61 include a hydraulic controller and a pressurized supply with a hydraulic medium. - The
legs 7 are each provided with a series of horizontal blind holes 62. When the jackingsystem 53 is not in operation, theleg 7 is locked to theplatform topside 5 by inserting abolt 63 into thehorizontal hole 57 of the fixedrest 55 and into a horizontalblind hole 62 of theleg 7 so that it is not displaceable in the axial direction. - The jacking
system 54 is a pin in hole system. Alternatively, a strand jacking system can be provided. - The
buoyancy cells 48 are measured such that thesuperstructure 39 is self-floating when thelegs 7 are mounted in the means for mounting 49 the legs and fixed by means of the jackingsystems 54. Thewater line 41 is thereby located below theprojections - Furthermore, the
platform topside 5 is designed such that it has a stable floating position when thelegs 7 are inserted into the lower andupper leg bearings projections water line 41 of thesuperstructure 39 is designed such that the taking on of ballast during the floating of thesuperstructure 39 can be foregone. - The weight distribution of the
platform topside 5 is approximately homogeneous. It is thus not necessary to use trim tanks to hold theplatform topside 5 in a stable trim. But trim tanks can be used, if needed. - The
platform topside 5 is self-floating and does not have its own drive. Thus, transport on a barge is not necessary. - For example, the platform topside has a length of 73 m, a width on the main deck of 49.5 m, on the bottom a width of 31.5 m and a height from the lower edge to the deck of 26.5 m.
- According to
FIG. 16 through 17 , the diameter of thelegs 7 at a short distance from their lower ends exceeds the inner diameter of theupper opening 35 of thepiles 4. There, each of thelegs 7 has aledge 64, under which its outer diameter is smaller than the inner diameter of thepiles 4 by a certain amount. On the bottom, thelegs 7 have afrustoconical section 65. - With the
frustoconical section 65, theleg 7 is insertable into theupper opening 35 of apile 4, until theledge 64 rests on the upper edge of thepile 4. A hollow-cylindrical gap 65 remains between the section with the reduced diameter of the leg and the pile. - In the example, the length of the
legs 7 is approximately 45 m. - The
platform topside 5 can be built in a construction dock of a shipyard. - During the construction phase, the
legs 7 are preferably inserted into the lower andupper leg bearings lower rest 55 by means ofbolts 63. - For the floating of the
platform topside 5, at least a temporary seal of theplatform topside 5 is ensured. - The
platform topside 5 is then floated at the setup site and hauled to the shipyard pier for final rig up and for testing. The installation of the removable components of the jackingsystem 54 can then take place on themain deck 47. - The
platform topside 5 is then floated to the installation site in the towing convoy with corresponding temporary firing. - At the installation site, the
platform topside 5 is floated into position above thesubstructure 2 and positioned on thesubstructure 2 with the help of tugboats at the defined point in time by positioners or respectively fenders in accordance with water level analysis. Thesubstructure 2 can hereby be used as an insertion and positioning aid. - The
legs 7 are then located in theprojections piles 4 of thesubstructure 2. - The
legs 7 are then lowered onto thepiles 4 by means of the jackingsystems 54 so that thelegs 7 engage with the lower ends into theupper openings 35 of thepiles 4 and fit with theledges 64. The lowering takes place by means of the jackingsystems 54 such that thehydraulic cylinders 61 are moved apart and the horizontal hole 60 of thedisplaceable rest 58 is aligned with ablind hole 62 of aleg 7. Abolt 63 is then inserted into the horizontal hole 60 and theblind hole 62 and thebolt 63 is pulled out of the fixedrest 55. - The
hydraulic cylinders 61 are then moved together whereby thelegs 7 are lowered. They were lowered until ablind hole 62 of theleg 7 is aligned with thehorizontal hole 57 of the fixedrest 55. Each of thelegs 7 is then secured by means of a bolt, which is inserted into thehorizontal hole 57 of the fixedrest 55 and theblind hole 62 of theleg 7. Thebolt 63 is then pulled out of thedisplaceable rest 58 and the processes described above are repeated until thelegs 7 are in their final position. - When the
legs 7 engage in thepiles 4 according toFIG. 18 , they are connected in a form-fit manner with the piles. For this, they are preferably grouted with the piles in that a grouting agent 67 is inserted into the gap 66. - The above work is comparatively easy to perform since the interface or respectively connection point between the
legs 7 and thepiles 4 is located above thewater surface 6 or not far below the surface of thewater 6. - After the establishment of a permanent connection between the
legs 7 of theplatform topside 5 and thepiles 4 of thesubstructure 2, theplatform topside 5 is raised to the predetermined installation height. The installation height is selected such that the highest possible wave (“century wave”) to be expected according to the water level analysis still passes below the platform topside. In the example, the installation height is 161 m above LAT. - The raising of the
platform topside 5 is performed by means of the jackingsystems 54. They are operated in the manner described above, wherein theplatform topside 5 is raised by pulling thehydraulic cylinders 61 together. Once theplatform topside 5 has reached the installation height, thelegs 7 secured in the end position by insertingbolts 63 into thehorizontal hole 57 of the fixedrest 55 and inblind holes 62 of thelegs 7. An elastically mounted bolt connection can be used for this. - The finished
offshore platform 1 is shown inFIG. 1 . Thecable tower 32 reaches up to alateral projection 42. There, abridge 68 is additionally attached, via which sea cables can be guided into theplatform topside 5 and the installation work is facilitated. - The above disclosure is intended to be illustrative and not exhaustive. This description will suggest many variations and alternatives to one of ordinary skill in this art. All these alternatives and variations are intended to be included within the scope of the claims where the term “comprising” means “including, but not limited to”. Those familiar with the art may recognize other equivalents to the specific embodiments described herein which equivalents are also intended to be encompassed by the claims.
- Further, the particular features presented in the dependent claims can be combined with each other in other manners within the scope of the invention such that the invention should be recognized as also specifically directed to other embodiments having any other possible combination of the features of the dependent claims. For instance, for purposes of claim publication, any dependent claim which follows should be taken as alternatively written in a multiple dependent form from all prior claims which possess all antecedents referenced in such dependent claim if such multiple dependent format is an accepted format within the jurisdiction (e.g. each claim depending directly from
claim 1 should be alternatively taken as depending from all previous claims). In jurisdictions where multiple dependent claim formats are restricted, the following dependent claims should each be also taken as alternatively written in each singly dependent claim format which creates a dependency from a prior antecedent-possessing claim other than the specific claim listed in such dependent claim below. - This completes the description of the preferred and alternate embodiments of the invention. Those skilled in the art may recognize other equivalents to the specific embodiment described herein which equivalents are intended to be encompassed by the claims attached hereto.
Claims (15)
1. A platform topside for an offshore platform comprising
a self-floating superstructure with a stable floating position,
projections on the superstructure,
means for mounting legs in an upright arrangement in the projections,
wherein the projections and the means for mounting legs are arranged above the water line or not far below the water line,
means for displacing the legs in the longitudinal direction of the legs in the means for mounting and
means for fixing the legs in their positions in the means for mounting.
2. The platform topside according to claim 1 , in which the legs are mounted in the means for mounting the legs and the superstructure equipped with the legs is self-floating with a stable floating position.
3. The platform topside according to claim 1 , in which the superstructure has projections on both sides of a center part or in which the structure has two side parts with these connecting projections in the form of a bridge.
4. The platform topside according to claim 1 , in which the means for mounting legs each have an upper leg bearing and a lower leg bearing arranged at a distance from it for mounting a leg.
5. The platform topside according to claim 4 , in which the upper leg bearings are integrated into the main deck of the superstructure and the lower leg bearings are integrated into a bottom wall of the projections.
6. The platform topside according to claim 1 , in which the means for displacing the legs are simultaneously the means for fixing the legs.
7. The platform topside according to claim 1 , in which the legs have on the bottom end a downward tapering cone and/or a ledge at a distance from the bottom end.
8. A method suitable for installing a platform topside of an offshore platform according to claim 1 , in which
the platform topside is constructed,
the platform topside is brought to the setup site in a self-floating manner,
the platform topside is positioned above a substructure,
the legs of the platform topside are lowered and connected with the substructure above the surface of the water or not far below the surface of the water,
the platform topside is raised with respect to the legs and
the platform topside is fastened on the legs.
9. The method according to claim 8 , in which the platform topside is equipped with the legs before being brought to the setup site.
10. The method according to claim 8 , in which the legs are connected with piles or towers of a substructure above the surface of the water or not far below the surface of the water.
11. The method according to claim 8 , in which the legs are connected in a form-fit manner with the towers and/or piles of a substructure.
12. The method according to claim 8 , in which the substructure is used as a positioning aid for the platform topside during the positioning of the platform topside above the substructure.
13. The method according to claim 8 , in which the means for displacing are at least partially dismantled from the offshore platform for other uses after the lowering of the legs and subsequent raising of the platform topside.
14. The method according to claim 8 , in which a cable tower on the substructure is connected with the platform topside after the raising of the platform topside.
15. The method according to claim 8 , in which the legs are connected with the substructure at a maximum of 6 meters, preferably 3 meters, more preferably 1.5 meters above or below the surface of the water.
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
EP12000732.3A EP2623675A1 (en) | 2012-02-03 | 2012-02-03 | Platform topside for an offshore platform and method for installing such a platform topside |
EP12000732.3-2315 | 2012-02-03 |
Publications (1)
Publication Number | Publication Date |
---|---|
US20130220203A1 true US20130220203A1 (en) | 2013-08-29 |
Family
ID=45654851
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US13/757,072 Abandoned US20130220203A1 (en) | 2012-02-03 | 2013-02-01 | Platform Topside for an Offshore Platform and Method for Installing Such a Platform Topside |
Country Status (3)
Country | Link |
---|---|
US (1) | US20130220203A1 (en) |
EP (1) | EP2623675A1 (en) |
KR (1) | KR20130090381A (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US10253475B2 (en) * | 2015-08-03 | 2019-04-09 | Ming Yang Smart Energy Group., Ltd. | Construction device and method for offshore wind turbine foundation with piling performed later |
US20200385946A1 (en) * | 2017-12-07 | 2020-12-10 | Ihc Holland Ie B.V. | A coupling system, an assembly of a vessel and a coupling system, and an assembly of a coupling system, jacket pile and foundation pile |
Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3716994A (en) * | 1971-06-28 | 1973-02-20 | Texaco Inc | Assembly system for a detachably connected offshore marine structure |
US3922868A (en) * | 1974-08-27 | 1975-12-02 | Reagan W Mcdonald | Deep water platform construction |
US4000624A (en) * | 1975-06-10 | 1977-01-04 | Lin Offshore Engineering, Inc. | Multi-component offshore platform |
US20060051164A1 (en) * | 2004-09-07 | 2006-03-09 | Offshore Technology Development Pte Ltd | Jackup oil rig and similar platforms |
Family Cites Families (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2967400A (en) * | 1955-08-08 | 1961-01-10 | James I Grant | Method and apparatus for erecting offshore platform |
DE2736937C3 (en) * | 1977-08-16 | 1981-04-16 | Howaldtswerke-Deutsche Werft Ag Hamburg Und Kiel, 2300 Kiel | Procedure for the construction of an offshore structure |
-
2012
- 2012-02-03 EP EP12000732.3A patent/EP2623675A1/en not_active Withdrawn
-
2013
- 2013-02-01 US US13/757,072 patent/US20130220203A1/en not_active Abandoned
- 2013-02-04 KR KR1020130012316A patent/KR20130090381A/en not_active Application Discontinuation
Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US3716994A (en) * | 1971-06-28 | 1973-02-20 | Texaco Inc | Assembly system for a detachably connected offshore marine structure |
US3922868A (en) * | 1974-08-27 | 1975-12-02 | Reagan W Mcdonald | Deep water platform construction |
US4000624A (en) * | 1975-06-10 | 1977-01-04 | Lin Offshore Engineering, Inc. | Multi-component offshore platform |
US20060051164A1 (en) * | 2004-09-07 | 2006-03-09 | Offshore Technology Development Pte Ltd | Jackup oil rig and similar platforms |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US10253475B2 (en) * | 2015-08-03 | 2019-04-09 | Ming Yang Smart Energy Group., Ltd. | Construction device and method for offshore wind turbine foundation with piling performed later |
US20200385946A1 (en) * | 2017-12-07 | 2020-12-10 | Ihc Holland Ie B.V. | A coupling system, an assembly of a vessel and a coupling system, and an assembly of a coupling system, jacket pile and foundation pile |
Also Published As
Publication number | Publication date |
---|---|
EP2623675A1 (en) | 2013-08-07 |
KR20130090381A (en) | 2013-08-13 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
US7234409B2 (en) | Vessel for transporting wind turbines, methods of moving a wind turbine, and a wind turbine for an off-shore wind farm | |
CN102124214B (en) | Support structure for use in offshore wind farm industry | |
US8911178B2 (en) | Device and method for erecting at sea a large slender body, such as the monopile of a wind turbine | |
US9004819B2 (en) | Installation method and recovery method for offshore wind turbine | |
US9234326B2 (en) | Base frame for an offshore platform and method for installing such a base frame | |
DK201170319A (en) | A self-propelled semi-submersible offshore wind farm installation vessel with a large crane | |
WO2016063210A1 (en) | Method for transporting a structure with buoyancy over water using a vessel, and vessel applied in the method | |
CN103255752B (en) | Support the buoyant support fixed platform of offshore wind turbine, marine works | |
CN110382344B (en) | Autonomous floatable gravity base for connection to an offshore facility | |
WO2018120280A1 (en) | Bottom-supported overwater platform and waterborne transport and mounting method therefor | |
WO2011102738A2 (en) | A method and vessel for offshore transport and installation of windmill assemblies | |
GB2378472A (en) | Method of constructing a floating offshore structure | |
US20130220203A1 (en) | Platform Topside for an Offshore Platform and Method for Installing Such a Platform Topside | |
WO2016079540A1 (en) | A floating support structure for a wind turbine and method for installing same | |
JPS6389715A (en) | Method for arranging prefabricated structure to sea bottom or river bottom and said structure | |
US4193714A (en) | Method for erecting a deck on a marine structure | |
CN116513384A (en) | Water floating platform device and installation method thereof | |
CN111279032B (en) | Harbour site and method for mooring a floating body in a harbour site | |
CN217870596U (en) | Tensioning type fan foundation anchored on foundation seabed | |
US8398338B2 (en) | Method for installing a topside module on an offshore support structure | |
TWI702327B (en) | Harbour plant and method for mooring a floating body in a harbour plant | |
ES2650735T3 (en) | Foundation Base | |
US20240270356A1 (en) | Installation System and Method For An Offshore Wind Turbine | |
WO2011071385A1 (en) | Floating marine structure with suction piles and vessela | |
US20240217629A1 (en) | Offshore submergible platform |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
AS | Assignment |
Owner name: NORDIC YARDS HOLDING GMBH, GERMANY Free format text: ASSIGNMENT OF ASSIGNORS INTEREST;ASSIGNORS:BOLLMOHR, THOMAS;HAGEMEISTER, CONSTANTIN;LINNEMANN, MATTHIAS;AND OTHERS;REEL/FRAME:030387/0184 Effective date: 20130425 |
|
STCB | Information on status: application discontinuation |
Free format text: ABANDONED -- FAILURE TO RESPOND TO AN OFFICE ACTION |