NO772098L - PLATFORM, ESPECIALLY FOR WORK AT SEA - Google Patents

Description

"Platform, especially for working in the sea, as well

procedure for assembling the platform".

The present invention relates to a platform, particularly for working in the sea, with a foundation, which is placed on the seabed and which exhibits at least one vertical pile (track) which is directed towards the seabed and protrudes from the bottom surface of the foundation. The invention also relates to a method for assembling such a platform for use in the sea.

When submerging foundations with large bottom surfaces, such as boxes, cell foundations for construction works, drilling platforms and the like, strong horizontal currents occur in the water below the bottom surface of the foundation during the immersion, which in particular immediately above the seabed assume high speeds and exert significant horizontal forces on the foundation, which forces immediately before and during the placement on the seabed - uncontrolled can displace the foundation laterally. It is therefore difficult to place the foundation on the seabed exactly in the desired location. There is also a risk that the downward-projecting sealing skirt arranged under the bottom surface of the foundation, which is supposed to counteract erosion of the seabed below the foundation, will be damaged. In order to slow down horizontal movements of the foundation just before placement on the seabed, it has previously been proposed to attach vertical piles (tracks) that project vertically down from the bottom surface of the foundation, and which penetrate into the seabed before the bottom surface of the foundation with the sealing skirts reaches the seabed, in order to prevent lateral displacement of the foundation in the last stage of the immersion. In this way, however, it is difficult to accurately calculate in advance the tip resistance and sheath friction for the piles, of which there are usually several, in the seabed,

and it may happen that the tip resistance and the mantle friction become so great that the piles do not penetrate further into the seabed and thus take over the full vertical force due to the weight of the foundation, so that the piles break and can damage the foundation when the piles are attached. In addition, it may happen that one or more piles encounter rocks or firmer bottom layers than other piles, and therefore penetrate less deeply or less quickly into the seabed. The foundation can thereby be left crooked, and considerable effort is required

to straighten the foundation. In some cases this is not possible at all.

An object of the invention is to overcome these difficulties

and to design the foundation so that the vertical load the piles are calculated for is not exceeded during any phase of the immersion, and that skewing of the foundation during immersion on the seabed is prevented. A further purpose of the invention is to arrive at a method for building a platform as indicated, which method can be carried out in a particularly simple way with the help of piles.

The first purpose is achieved by the pile or piles being arranged sealingly and axially displaceable in a guide chute which is adapted to the cross-section of the pile, which chute can be closed at the upper end and together with the pile forms a pressure chamber which has an adjustable pressure limiting valve.

This construction has the advantage that the pile can slide upwards

in the guide shaft as soon as the vertical forces affecting the pile from the seabed during the immersion exceed a specific, highest permitted value. The upper end of the pile is thereby displaced like a piston in a cylinder, in which is enclosed a pressure medium which can escape through a pressure limiting valve as soon as the limit pressure in the pressure chamber is exceeded. As this pressure is adjustable, the penetration depth of the piles can be adapted to the bottom

the conditions on the seabed. Furthermore, it is possible to completely relieve the pile of pressure in the guide shaft, so that the entire vertical force acts on the foundation as soon as the piles have done their stabilizing effect and thereby completed their task,

so that the foundation with the sealing skirts penetrates all the way into the seabed and rests against it with its bottom surface,

so that the foundation during the immersion is controlled by the piles that are stuck in the seabed.

As soon as the piles have penetrated the seabed so that the resistance forces in the bottom can be utilised, the piles are also capable of absorbing vertical loads. By arranging several piles, it is thereby possible to lower the foundation, which in the last phase of the sinking is controlled by the piles, exactly horizontally down to the seabed, or align the foundation above the seabed horizontally on the piles.

The pressure limiting valve can be built into a line

which connects the pressure chamber with a container for pressure medium. Furthermore, the pressure limiting valve can suitably be designed as a shut-off valve, whereby a closeable filling and emptying valve is connected in parallel with this. This embodiment has the advantage that the pressure medium in the pressure chamber, which can conveniently be water, can be collected and pumped back to the pressure chamber when the foundation is to be raised on the piles that protrude into the seabed, to align the foundation or to loosen the bottom surface from the seabed.

The pile and its guide shaft can have different cross-sectional shapes. Suitably, both are cylindrical and each is hemispherically designed at the upper end, as this shape is easy to manufacture, provides easy assembly and is best adapted to the occurring pressure conditions.

The guide shaft is appropriately closed by a hemispherical cover which is attached pressure-tight and releasably to the guide shaft and rests against a support structure mounted on the foundation. The upper, hemispherical end of the pile fits into this

upper, hemispherical cover, so that the pile can be guided completely into the guide shaft. Because the cover is removable, it is possible,

after the completion of the foundation in a dock, as well as the launching of the foundation, to drive the pile from above down into the guide shaft and only then to close the guide shaft above. This is important for foundations with a large building height, where there is no free space in the dock below the bottom surface.

The wall and/or hemispherical cover for the guide shaft

can consist of concrete or steel. It is also possible to make the wall of the guide shaft in the interior of the foundation from concrete or prestressed concrete and to line it with a steel pipe or to enclose it.

On the inner surface of the wall in the guide shaft for the pile is arranged

at least an annular chamber, in which there is a sealing ring of elastic material which is pushed against the outer circumference of the pile by a pressure hose which is expandable by means of a pressure medium and is arranged on the outside of the sealing ring. Such a seal, several of which are suitably arranged in different chambers in the axial direction of the guide shaft, one after the other almost like a labyrinth seal, enables a secure sealing of the pile in the guide shaft as well as enabling axial movement of the pile at the same time. In this way, the installation pressure for the seal can be varied and adapted to the occurring pressure in the pressure chamber in the guide shaft.

For the transmission of the horizontal forces from the pile to the foundation and vice versa, several guide and support rings are appropriately arranged on the inner surface of the wall of the guide shaft, which guide the pile and keep it at a distance from the wall of the guide shaft.

At the upper end, the pile itself can have a support ring placed around the circumference, which support ring interacts with one of the guide and support rings. This support ring holds the pile in its lowest position during immersion. • At the same time, the support ring limits the vertical movement of the foundation when it is raised on the piles that protrude into the seabed, for aligning or raising the foundation from the seabed.

According to the invention, the guide shaft is so long that it

can occupy the pile at least to such an extent that its lower end does not protrude from the bottom surface of the foundation. This design has the advantage that the arrangement of the piles does not require any additional floating height above the seabed when the foundation is to be transported to the site of use along a relatively flat bottom.

In order to facilitate the insertion of the pile after the completion of the foundation and later to be able to pull the pile completely into the guide shaft, the pile is suitably suspended in a pulling device which is passed sealingly through the cover for the guide shaft and is attached to a lifting device.

It is particularly advantageous to design the pile as an open downwards

pipe whose interior is in pressure equalizing connection with the surrounding water. This design has the advantage that the tip resistance of the pile when sinking into the seabed is very small. At the same time, the pressure compensation line prevents

after penetration of the pile into the seabed, a water pressure builds up in the interior of the pipe which makes it difficult for the pile to penetrate unimpeded.

In order not to burden the foundation with extra ballast during transport and during immersion, the pile tube can have an air-filled buoyancy chamber.

The described pressure equalization line is formed appropriately

of a pipe which is passed through the pressure chamber in the guide shaft and possibly the buoyancy chamber in the pile, and which is slidably sealed in the cover of the guide shaft and at the same time serves as a pulling device for the pile, to which the lifting device is attached. In the cover for the guide shaft, the pressure equalization pipe can thereby

be sealed using a stuffing box. Such a construction is particularly simple and provides problem-free lowering and raising of the pile pipe in the shaft and at the same time a pressure equalization in the pile pipe.

The piles arranged according to the invention in the foundation can also serve as guides for the foundation when submerged on a flat seabed. In addition, the piles enable the floating of other building parts over foundations, e.g. a drilling platform to be attached to the foundation, as the pilings during the floating keep the foundation immovably fixed to the bottom in calm seas.

These advantages can also be exploited by a method

for the assembly of a large platform for use in the sea, which platform exhibits a foundation for immersion to the seabed, with vertically insertable piles in its bottom surface and with support legs attached to the foundation.as well as equipped with a floating, vertically displaceable deck on the support legs. The method according to the invention comprises placing the foundation with the load-dependent, displaceable piles on the seabed and, after the piles have been driven into the seabed, lowered so far, while controlling the piles, that the surface of the foundation is at least a length equal to the immersion depth for the floating deck below the surface of the water, and that the deck is then floated over the foundation and, after raising the foundation to the surface of the water, attached to the support legs.

This method has the advantage that the foundation is prepared

in a dock alone, without outriggers and deck>after completion of construction can be launched and lowered below the surface of the water in shallow water near the shipyard or workshop that manufactures the deck and possibly also the outriggers. In this way, the piles can guide the foundation in a safe way during the immersion when the foundation assumes an unstable floating position upon complete immersion in the water. The entire deck can then be floated over the foundation and connected to the support legs with which the foundation is equipped.

It is particularly advantageous to attach the support legs to the foundation before floating the deck and to float the deck in several floating parts between the high-bearing support legs and over the foundation and to join the parts on this. These features are particularly advantageous because the preparations for the work of placing equipment on the deck for the work to be carried out with the platform take a long time, during which the preparation of the foundation and support legs as well as their assembly can take place.

According to a further feature of the invention, the push-in piles after penetration into the seabed can be used as

control when lowering and raising the foundation in calm seas.

In what follows, the description will be described in more detail based on

an embodiment shown in the attached drawings.

Fig. 1 shows a deep-water platform for oil drilling, with

a foundation, according to the invention, in a submerged state, seen from the side.

Fig. 2 shows the object in fig. 1 in a horizontal section after

the line II-II in fig. 1.

Fig. 3 shows a vertical section along the line III-III, enlarged

yardstick.

Fig. 4, 5, 6 and 7 show the details IV, V, VI and VII in fig. 3 in

enlarged scale.

Fig. 8, 9, 10 and 11 show the assembly of a platform according to the invention in four different phases,

seen from the side.

In fig. 1 shows a platform 10 for carrying out work

in the sea, which platform e.g. can be used as a drilling platform for drilling for oil in deep water. The platform consists of a floating deck 11 which carries the work equipment, such as e.g. derrick 13, a crane 14 and room 15 for the workers,

and which is suspended vertically displaceably on four tubular supports 16 which are anchored to the floating foundation 17. The foundation 17 consists of several laterally interconnected cells 18 which enclose a large box 19, which partly contains ballast in the form of sand, mud or similar and which can be partially floated and lanced. The cells 18 in the foundation 17 can be filled with water or oil and floated or lanced, forming together with the box 19 a closed foundation 17 with a large base surface which is placed on the seabed 20.

!

To avoid erosion under the bottom surface 21 of foundation 17,

in the bottom surface 21 of the foundation 17, protruding skirts 22 are placed which consist of relatively thin steel sheets, so that they can easily penetrate into the seabed 20.

For lateral stabilization of the foundation 17 in the last phase of the immersion, in the spaces 23 between the four supports 16 and the cells 18 that surround the supports on the outside are arranged

a pile 24. These piles 24, of which there may be several distributed over the entire base surface of the foundation 17, project perpendicularly down from the bottom surface 21 when the foundation 17 is submerged, and must penetrate the seabed 20 during the immersion before the skirts 22 reach down to the seabed 20. Each pile 24 consists of a steel tube 26 which is open at the lower end 25, and which is closed at the upper end 27 with a hemispherical capsule 28. The upper part of the pile tube 26 is divided by means of an intermediate wall 28 ', and forms an air-filled buoyancy chamber 29 through which a tubular pressure equalization line 30 is passed and is welded to the hemispherical capsule 28 and to the intermediate wall 28'.

As can be seen from fig. 3, each pile 24 is arranged in a cylindrical guide shaft 31 adapted to the cross section of the pile. The guide shaft 31 is open at the lower end 32 and closed at the upper end by a hemispherical cover 34 made of steel, which with a ring flange 25 is releasably and pressure-tightly attached to an upper step 36 in the guide shaft 31. The cover 34 is supported against a support structure 37 mounted on the foundation 17, which support structure is formed by cross-arranged steel beams 38, 39 and circularly cut support plates 40 which rest against the outer surface of the hemispherical cover 34.

The pressure compensation line 30 which is attached to the pile pipe 26

is passed through the cover 34 for the guide shaft 31, and sealed against this with a stuffing box 41. This stuffing box construction 41 is shown on an enlarged scale in fig. 7, and consists of a steel ring 42 with a C-shaped cross-section, attached to a lining disc 35' which is welded to the cover 34 and surrounds the pressure equalization pipe 30 with a small distance. The gap 43 between the ring 42 and the outer surface of the pressure compensation tube 30 is filled with an elastic

or plastically deformable mass 44, which is compressed from above by the lower edge of a pressure ring 46 with an angular cross-section, which lies closely against the pressure equalization pipe 30 and can be pulled by means of screws 47 and nuts 48 in the axial direction of the pressure equalization pipe 30 towards the upper flange 49 of the C-shaped ring 42.

Attached to the upper end 50 of the pressure equalization pipe 30 is a vtirek flap 51 to which the hoist rope 52 for a hoist device, not shown, can be connected by means of a shackle 53 or the like. The guide shaft 31, which is limited at the top by the cover 34, is so long that the pile 24 can be raised so far that its lower end does not protrude from the bottom surface 21 of the foundation 17. The walls 54

in the guide shaft 31 as well as the other parts of the foundation 17 can suitably consist of reinforced concrete, and can be lined with a steel pipe or surrounded by a steel pipe. On the inner surface 55 of the wall 54 in the guide shaft 31, several guide and support rings 56 of steel are arranged at an axial distance from each other, which slightly protrude from the inner surface 55 of the wall 54 and are in sliding guide contact with the outer surface of the pile tube 26

and also keeps this at a distance from the inner surface 55 of the wall 54.

The top guide and support ring 56 cooperates with a support ring 57 which is located around the upper end 57 of the pile 24, with which support ring the pile pipe 26 in the submerged state rests against the top guide and support ring 56 (fig. 6).

Between the two upper guide and support rings 56, a sealing device 58 is arranged on the inner surface 55 of the wall 54 in the guide shaft 31, which fits tightly around the outer circumference of the pile pipe 26 and forms a pressure-tight separation between the upper and lower part of the guide shaft 31, so that a pressure chamber 59 is formed between the cover 34 for the guide shaft 31 and the spherical cap 28 on the pile pipe 26.

In fig. 5, the sealing device 58 is shown in more detail. It consists of several chambers 60 arranged one after the other in the axial direction of the guide shaft 31, and is bounded towards the guide shaft by end walls 61 and separated from each other by intermediate walls 62. In each chamber 60 is arranged a sealing ring 63 of elastic material, e.g. . rubber, and which is pressed against the outer surface of the pile pipe 60 by a pressure hose 64. The pressure hose 64 is also located in the chamber 60, and is laid around the outer circumference of the sealing ring 63. The interior of the pressure hose is connected to a pressure line 66 which can be closed using a valve 65,

and through the pressure line 66 a pressure medium can be passed, e.g. water or compressed air, to the interior of the pressure hose 64,

which expands the hose and thereby presses the sealing ring 63

against the wall of the pile pipe 26. The size of . the air pressure in the pressure hose is adjusted so that the pressure chamber 69, which is filled with water under pressure, is sealed, at the same time that it enables sliding movement of the pile 24 towards the sealing device 68. By pressing the sealing ring 63 against the wall of the pile tube 26, the entire sealing device is emptied of air , respectively water,

by means of not shown holes 61 and 62 in the chamber walls. The holes are connected by wires 75, indicated by dashed lines,

which leads to the surrounding water.

An air line is connected to the cover 34 in the guide shaft 31

67 with valve 68 and a water line 69, which lines split into a supply line 71 with filling valve 72, and which leads to a water pump not shown, as well as an outlet line 70 which leads to a collection container not shown, since in the outlet line 70 an adjustable pressure limiting valve 73 is built in. The pressure limiting valve 73 is also designed as a shut-off valve.

After the completion of the foundation 17 in a dock, the pressure hoses 64 and the sealing rings 63 in the sealing device 58 are built in and connected. Then, with the help of a floating crane or the like, the pile pipe 26 is guided from above down into the guide shaft 31, until the support ring 57 on the pile pipe 26 rests against the uppermost guide and support ring 56. Then the shaft cover 34 is placed over the pressure equalization pipe 30 and with its flange 35 attached to the upper end 33 of the guide shaft 31. The stuffing box is then attracted into the cover, and the pressure equalization pipe 30 is attached to the rope 52 for the raising and lowering device.

With the lifting device then, when the air discharge valve 68 is open, during simultaneous air discharge from the pressure chambers 59, the pile pipe 26

pulled up so high that the lower end 25 no longer protrudes

down from the bottom surface 21 of the foundation 17. The filling line 71 is then connected to the water pump and the outlet line 70 is connected to the collection container. Thus, the pile 24 is fully assembled1",

and the platform can be launched and floated to the place of use. Below, it is essential that the pile 24 does not project down from the bottom surface 21 in the foundation 17 and further increases the large immersion depth (floating depth) for this.

At the site of use, before the foundation is lowered, the pile pipe is lowered with the lifting device while simultaneously releasing air from the pressure chambers 59 so far down the guide shaft 31 that the bearing ring 57 on the pile pipe 26 rests against the uppermost guide

and support ring 56. The lifting device is then relieved. The pressure hoses 64 are pumped up with compressed air, which presses the sealing rings 63 against the outer wall of the pile pipe 26. Then the pressure chamber 59 is filled with water under pressure during simultaneous air release through the air line 67. Then the shut-off valve becomes

73 closed bg the pressure limiting valve close to the pressure which

multiplied by the cross-sectional area of the pile tube 26 gives the maximum vertical force that the pile 24 can and must absorb.

During the subsequent lowering of the foundation 17 down to the seabed 20, the piles 24 that project down from the bottom surface 21 and the lower edge of the skirts 22 will first hit the seabed, and penetrate under the load from the foundation into the seabed 20 and stabilize the foundation 17, as the piles occupy and transfers to the seabed the horizontal forces exerted due to the strong horizontal currents between the foundation 17 and the seabed 20. The foundation is thus riveted to the seabed

and cannot perform any horizontal movements when the skirts 2 2 reach the seabed and begin to be pressed down into it.

When the tip resistance and sheath friction for the piles 24 becomes

so large that these under the load of the foundation do not easily penetrate further into the seabed, the pressure increases in the pressure chamber 59 in the guide shaft 31. The pressure limiting valve reacts

on this increase in pressure and releases as much water from the pressure chamber

59 and into the collection container which is connected to the line 70 that the pressure in the pressure chamber 59 is kept constant. This is ensured

that the vertical load from the foundation as a pile 24

is intended to be occupied should it not be exceeded, so that no damage can occur to the foundation 17 in the attachment points for the piles 24. In the last phase of the immersion, the guide chambers are threaded down over the piles 24, which thereby slide into the guide chambers until the steel skirts 22 penetrate into the seabed 20. At approximately this time, the shut-off valve 72 is opened, so that the water can flow freely out of the pressure chamber 59, whereby the excess pressure in the chamber disappears. The total load from the foundation 17 now acts only on the steel skirts 22,

so that these can penetrate into the seabed 20 without being slowed down by the piles 24, until the entire bottom surface 21 of the foundation 17 rests against the seabed 20.

It will be realized that it is possible to raise the foundation 17 from the seabed with the help of the piles 24 until the pressure limiting valve is closed and water under pressure is pumped through the valve 72 and into the pressure chamber 59. This pumping in of water under pressure naturally takes place at the same time as the cleaning of the buoyancy chambers in the foundation, as the piles 24 are not supposed to lift the entire load of the foundation, but only contribute to raising it from the seabed, as the foundation is in a way stuck after a long time and is difficult to loosen even with large buoyancy forces.

When the foundation is detached from the seabed, by continued movement in the water, the pile tubes 26 are pulled up from the seabed 20, as these with the support rings 57 rest against the upper guide and. support rings 56. As soon as the pile tubes are free, they can be pulled back into the guide shafts 31 hanging from the ropes 52 by means of the hoisting device, whereby the valve 72 is opened so that the water can flow out of the pressure chamber 59 and into the collection container.

It will be realized that when the pile tubes 26 penetrate into the sea bed 20 no water pressure can build up in the pile

the pipes, as the water contained in the lower part of the pile pipes can escape upwards through the pressure equalization pipe 30. The buoyancy chamber 29 ensures that the weight of the pile pipe 26 is equalized and that great forces are not needed to lower and raise the pile pipe in the guide shaft 31 below water.

U.S

In fig. 8 to 11 shows a particularly advantageous method for assembling the platform. Hereby, the foundation 17, after completion, is launched from the dock and brought to the vicinity of the construction site or the shipyard that manufactures the support legs and the deck and the equipment to be mounted on it. -The foundation is lowered to the seabed in shallow water, whereby the piles 24 penetrate into the seabed 20.

As soon as the tip resistance and the sheath friction of the piles in the seabed have become large enough to completely absorb the load from the foundation 17, the foundation is lowered, so far and possibly placed on the seabed 20 that the surface 80 of the foundation 17 is a distance t below the water surface 81, whereby the distance t is at least so. as large as the floating depth T for the deck 11. During the immersion, the foundation is guided on the piles 24, which, before the surface 80 of the foundation dives into the water, penetrate into the seabed 20 and are pushed into the guide chambers by increasing tip resistance and mantle friction.

The construction of the support legs can conveniently begin while the surface 80 of the foundation. 17 protrudes above the surface of the water.

When the foundation is submerged, the piles 24 take over the guidance and stabilization of the foundation 17, which is in an unstable floating position upon complete immersion in water.

Later, the deck 11, which is produced in a shipyard in several parts, suitably a central part and two side parts, is floated between the support legs 16 above the foundation 17 and joined to this, after which the foundation 17 can again be raised to the water surface 81 on the piles 24. In this way, it is possible to mount the deck 11 after the completion of the support legs 16, whereby time has been gained during the completion of the deck and the fitting of the support legs 16.

The invention is not limited to the embodiment. E.g. it is also possible to arrange massive piles, or to make the guide shaft from a steel pipe. Furthermore, the piles do not need to have . circular cross-section, but may also have another cross-sectional shape, in case this is appropriate. It is also possible to design the sealing devices differently, without thereby exceeding the scope of the invention.

Claims (24)

1. Platform, particularly for work in the sea, comprising a foundation which is arranged to be lowered onto the seabed and which exhibits at least one vertical pile directed towards the seabed and projecting down from the bottom surface of the foundation, characterized in that the pile (24) is arranged o sealing and axially displaceable in a guide shaft (31) adapted to the cross-section of the pile, which guide shaft can be closed at the upper end (33) and together with the pile (24) forms a pressure chamber (59) which has an adjustable pressure limiting valve (73). 2. Platform as stated in claim 1, characterized in that the pressure limiting valve (73) is built into a line (70) which connects the pressure chamber (59) with a container for liquid under pressure. 3. Platform as specified in claim 1 or 2, characterized in that the pressure limiting valve (73) is also designed as a shut-off valve, and that a closeable filling and emptying valve (72,) is arranged parallel to this. 4. Platform as stated in claims 1-3, characterized in that a valve (68) is arranged at the upper end (33) of the guide shaft (31) for letting in and releasing air. 5. Platform as stated in claims 1 - 4, characterized in that the pile (24) and its guide shaft (31) have a cylindrical cross-section and at the upper end (27, 33) are designed as hemispheres. 6. Platform as stated in claims 1-5, characterized in that the guide shaft (31) is closed by a hemispherical cover (34) which is attached pressure-tight and releasably to the guide shaft (31) and rests against a support structure (37) mounted on the foundation .(17). 7. Platform as stated in claims 1-6, characterized in that the lines for air and pressure medium (67, 70, 71) are connected to associated valves (68, 72, 73) on cover/b (34) for the guide shaft (31) . 8. Platform as stated in claims 1-7, characterized in that the wall (54) and/or the hemispherical cover (34) for the guide shaft (31) consists of concrete. 9. Platform as stated in claims 1-8, characterized in that the wall (54) of the guide shaft (31) and the cover (34) consist of steel. 10. Platform as stated in claims 1-9, characterized in that the wall (54) of the guide shaft (31) is lined with a steel pipe and/or surrounded by a steel pipe. 11. Platform as stated in claims 1-10, characterized in that on the inner surface (55) of the wall (54) in the guide shaft (31) there is arranged at least an annular chamber (60) in which there is a sealing ring (63) of elastic material and which is pressed against the outer circumference of the pile (24) by a pressure hose (64) arranged on the outside of the ring which can be expanded by a pressure medium. 12. Platform as stated in claims 1-11, characterized in that several chambers (60) with clamp (and sealing rings 63) are arranged one after the other in the axial direction of the guide shaft (31). 13. Platform as specified in claims 1-12, characterized in that guide and support rings (56) are arranged on the inner surface (55) of the wall (54) in the guide shaft (31) which guide the pile (24) and keep it at a distance from the wall (54) in the guide shaft (31). 14. Platform as stated in claims 1-13, characterized in that the pile (24) at its upper end (27) has a support ring (57) along its outer circumference, which support ring interacts with one of the guide and support rings (56). 15. Platform as stated in claims 1-14, characterized in that the guide shaft (31) is so long that it can take up so much of the pile (24) that the lower end (25) of this does not project down from the bottom surface (21) of the foundation (17). 16. Platform as stated in claims 1-15, characterized in that the pile (24) is suspended in a traction device (30) which is led sealingly through the cover (34) for the guide shaft (31) and attached to a lifting device. 17. Platform as stated in claims 1-16, characterized in that the pile (24) is a pipe (26) which is open at the lower end (25), and whose interior is connected to the surrounding through a pressure equalization line (39) water or a collection container. 18. Platform as stated in claims 1.-17, characterized in that the pile tube (24) has an air-filled buoyancy chamber (29). 19. Platform as stated in claims 1-18, characterized in that the pressure equalization line (30) consists of a pipe which runs through the pressure chamber (59) in the guide shaft (31) and possibly through the buoyancy chamber (29) in the pile (24), and is arranged for sealing sliding movement in the cover (34) for the guide shaft (31) and at the same time serves as a pulling device for the pile (24), to which pulling device the lifting device is attached. 20. Platform as stated in claims 1-19, characterized in that the pressure equalization pipe (30) in the cover (34) for the guide shaft (31) is sealed by means of a <p> ackbox (41). 21. Method for assembling a large platform for use in the sea, particularly as specified in claims 1 - 20, which exhibits a foundation with vertically insertable piles in its bottom surface, which is arranged to be placed on the seabed, to which foundation are attached support legs and a vertically displaceable, floating deck on these, characterized in that the foundation (17) is first placed with its load-dependent, displaceable piles (24) on the seabed (20) in calm seas, and that the piles (24) after penetration into the seabed (20) is lowered while steering along the piles (24), so deep that the surface (80) of the foundation (17) is at least a length equal to the immersion depth (t) of the floating deck (11) below the water surface (81), and that then the deck (11) is floated over the foundation (17) and after raising the foundation (17) to the water surface (81) is attached to the support legs (16). 22. Method as stated in claim 21, characterized in that the tire (11) is floated in several floating parts over the foundation (17) and joined to this. 23. Method as stated in claim 21 or 22, characterized in that the support legs (16) are attached to the foundation (17) before floating the tire (11) and that the parts of the tire (11) are floated between the upstanding support legs (16) over the foundation ( 17). 24. Method as specified in claims 21 - 23, characterized by . that the push-in piles (24) after penetration into the seabed (20) are used as control when lowering and raising the foundation (17).