NO135216B - - Google Patents

Description

This invention relates to a work construction for carrying out work operations on the seabed, designed to work

those in connection with a pontoon, floating platform, jetty etc.

Most work on the seabed is carried out with the help of divers

kerer As long as it concerns relatively small depths, e.g.

down to 10 m, work on the seabed can be carried out relatively quickly and without too many complications, but the working conditions and thus the work efficiency change - as the depth increases. As the diver must decompress during or after ascent,

the effective working time is small. Diving work is not without danger as the diver can be exposed to diving sickness, lung burst etc. Therefore, the diver's salary is relatively high and there is also a shortage of qualified divers.

From the above it should be clear that there is a need for new systems.

more or constructions that make it possible for a good deal of work

there on the seabed within a reasonable depth range, e.g. down to 30m, can be carried out without or essentially without the help of diving

re.

The purpose of the invention is to provide a construction

tion that satisfies the aforementioned need. The construction must be easy to manufacture, transport and it must also be easy to use and easy to maintain. Furthermore, the work structure must be suitable for carrying out smaller works, where the freedom of movement for the structure and the machine is relatively limited and where the bottom conditions can be difficult, e.g. of mixed nature

hot.

In the U.S. patent 3 310 892, an underwater digging unit or dredging unit has previously been proposed which, through a snorkel tube with a cross-section larger than that of a manhole, is connected to a large floating buoy which partly also serves as a work platform. Machines of this type are only suitable for use in places where the bottom conditions are particularly favorable, e.g. flat sandy bottom. The unit is suitable for digging long trenches,

but cannot be used, for example, for cleaning the bottom in connection

see with casting of bridge pillars, piers etc.

It is also previously known that a building structure, e.g. wellhead top, on the seabed using a pipe shaft can be connected to the atmosphere above the water surface after the bottom work has been carried out with the help of divers. The pipe shaft and the pontoon which controls the upper part of the shaft are anchored in the completed bottom structure. Such an embodiment is i.a. shown and discussed in the U.S. patent 2 534 480 and is not suitable for carrying out operations other than certain service work within the cross-section of the pipe shaft itself. All other work must be carried out with the help of divers or other auxiliary equipment.

Equally opposite to what has just been mentioned is the purpose

with the invention to provide a working structure which allows the execution of initial works on previously untouched ground which can be quite rough and where the working area can extend from a few square meters up to e.g. 2-300 m depending on the nature of the work machine, without it being necessary to move the entire work structure.

The work structure according to the invention is distinguished by the features specified in the patent claims.

The work construction is advantageous in that the operator can go down into the construction's maneuvering chamber and operate the work machinery under atmospheric pressure. A further advantage consists in the applicability of the construction, as this e.g. in connection with excavator equipment can perform approximately the same work on the seabed as an excavator performs on land. As the pipe structure's maneuvering chamber can be equipped with windows, it is possible to use the structure to carry out observations on the seabed without the work machine being in operation. The construction can then be used at various support depths than e.g. for digging.

The invention shall be explained in more detail by means of examples with reference to the drawings, where: Fig. 1 shows an elevation of a working structure according to the invention seen in working position and suspended in a floating pontoon, fig. 2 shows a horizontal section along the line II-II in fig.

1, fig. 3 a diametrical longitudinal section through the main section of the structure, fig. 4 a cross-section along the line IV-IV in fig. 3. Fig. 5

shows in diametrical section a rotatable machine foundation arranged on the construction's work console and fig. 6 shows the construction in surface position during work at shallow depth.

Fig. 1 shows a plan view of a working structure 1 made in accordance with the invention and placed in working position on the seabed 3 by means of a floating pontoon 2. The latter is anchored to the bottom by means of chains 4 and is designed in the middle with an oblong well 5 which is open towards one side of the pontoon 2, in this case in a direction perpendicular to the plane of the drawing and towards the viewer. Alternatively, the pontoon 2 can include e.g. two parts 2'. 2" which are appropriately connected to each other to form the aforementioned well. The pontoon 2 carries a lift tower or a similar structure 6. On the pontoon deck are hoist winches 7, air compressors 8, hydraulic pumps 9, drive devices 10 for operating the various aggregates, an operator's stand 11 and a number of other devices that are necessary for the operation of the pontoon and the structure.

The work construction 1 generally comprises a pipe string with a number of joint sections 12 (only one is shown) and a main section or bottom section 13 made with a significantly larger diameter than the joint section. The joint section can e.g. be made with a diameter of 0.7 m and the main section with a diameter of 1.2 m. All joint sections 12 and the main section 13 at the top are equipped with joint flanges 14. Adjacent flanges are bolted together in a known manner and a seal (not shown) is placed between the flanges to prevent the ingress of water.

The main section 13 has at the top a transition part 15 with a reduced diameter for adaptation to the nearest joint section. Below, the main section 13 is closed with a bottom 16, which can best be seen in fig. 3. According to this figure, the bottom is flat, but it can also be hemispherical. from the bottom extend downwards two strong flanges or ribs 17 respectively. 18 which cross each other along the axis of the main section. At the point of intersection, an axial grab bar 19 is arranged which is welded together with the ribs and projects outside these in a downward direction, so that it can grip the seabed 3 when the structure is lowered.

On top of the top joint section 12 is a cap 20 which prevents the ingress of rain, snow e.1. The hood can be provided with a hatch 21. All sections are provided with lifting flanges or lifting lugs 22. From the top section, cables 23 extend over top guide rollers 24 to the pontoon's lifting winches 7. As shown in fig. 1 and particularly in fig. 2, the main section 13 on the outside is equipped with a pair of axis-parallel T-shaped slide guides, which e.g. can be between 2 and 4 meters long. The sides 26 of the slide guides are welded to the wall of the main section 13 as shown in fig. 2. Below, the guides 25 end in a support projection 27.

The main section 13 carries a working machine foundation 30. This foundation is designed as a box-shaped console or cantilever which is equipped on one side with a pair of parallel slides 32 which interact with the slide guide 25 on the main section 13 and which on the same side carries two beam columns 33 as at the top carries a further pair of slides 34, which, in the same way as the slides 32, are arranged in sliding engagement with the slide guides 25 on the main section. The foundation console 30 can therefore be moved up and down along the main section to a limited extent.

As fig. 1 shows, a support base 35 is arranged on the foundation 30, which carries a rotatable hydraulic excavator 36 on this arrangement. The excavator is hydraulically driven and in this case is designed as a backhoe with a backhoe bucket 37. The excavator's outrigger 38 is stored pivotably on the machine's own foundation 39 which is stored rotatably on the base 35. 40 schematically shows a hydraulic pressure line which carries pressure medium to the various drive parts in the excavator. The console or foundation 30 is, in the same way as the main section 13, on the underside equipped with one of flanges or ribs consisting of a pointed section at the bottom with a pin 42 for engagement with the seabed.

If necessary, the work structure can be equipped with a work machine other than an excavator, e.g. a drilling unit, a mud cleaner, a bottom scrubber, etc. If the construction is equipped with an excavator, it is also possible to bolt on the excavator's bucket or outrigger, e.g. a chain feeder for rock drilling.

Fig. 3 shows a longitudinal section through the main section 13 and fig. 4 shows a cross-section along the line IV-IV in fig. 3. The main section 13 surrounds an operating chamber 45. Between the bottom of the operating chamber 46 and the bottom of the main section, a ballast tank 49 is arranged whose contents can be adjusted as required. On the wall of the operating chamber 45 and the transition 15, there are arranged leaders 47 respectively. 48. A fresh air line 28 extends from a fresh air fan on the pontoon (not shown) down into the operating chamber. 51 denotes a compressed air line that extends from a compressor on board the tank and 52 and 53 flow line and return line for hydraulic fluid. A maneuvering center for the work roa rail is indicated at 54 and a distribution valve for the compressed air at 55. Likewise, a TV monitor 56 is indicated in the operating chamber. A working panel 58 is also implied to be arranged in the operating chamber.

Fig. 5 schematically shows a diametrical section through the console foundation. The top 30 of the console carries a low, cylindrical or ring-shaped base 35 which is welded to the part 30 and which, by means of roller and/or ball bearings, carries a rotatable machine foundation 39 which is also shown in fig. 1. The design is such that lowers are located in the upper part of the foundation. The machine foundation 39 has a larger diameter than the base 35 and protrudes a good distance below the upper edge of the base. Inside the foundation there is an outlet for a compressed air line 60. When the foundation is in surface position, the entire foundation housing will be filled with air. When the structure is lowered, an air cushion will form in the upper part of the foundation and prevent water from penetrating. As the depth increases, it may be necessary to supply compressed air through line 60 to maintain the height of the air cushion, which must be such that the bearings do not come into contact with the water. Oil can be used instead of air, but then the outer housing must be provided with a bottom wall and seals that prevent the oil from flowing out when the foundation is raised to surface position and the water pressure disappears.

When the structure is lowered towards the bottom and the console 30 carries e.g. an excavator, it must be assumed that the pipe string will come out of plumb (at the above-mentioned dimensions a maximum of approx. 1.5 m). Before the console's gripping pin 42 touches the bottom, the operator lowers the digging bucket 37 and maneuvers the pipe string using the hydraulics to vertical position. The immersion can then continue. If the work console is without an excavator or other tool that can be used in a similar way, provision must either be made for balancing the pipe string or for such a suspension that the gripping pin 19 under the main section will take the correct position in relation to the pontoon. This can be done by appropriate adjustment of the wire tension in the wires 23.

Often the depth will be so great that several sections have to be joined together. The main section 13 is then lowered so far down that its top flange 14 comes approximately at the height of the pontoon's work table 28, after which a joint section 12 is set up and bolted together with the main section. The structure is then lowered a bit downwards and the next joint section 12 is flanged on if necessary. The length of the joint sections can be approx. 5 m and the weight will then be approximately 1800 kg per section. During the immersion and joining of the sections, the ballast tank 49 is adjusted as required. At the end of the immersion operation, the console pin 42 and the main section pin 19 will become stuck in the bottom and flanges. 17,18,41 will partially dig in and ensure a reliable anchoring during the work. Lifting and dismantling the structure is carried out in reverse order. Also during this operation, the ballast tank's contents are adjusted as required.

Fig. 6 shows the construction in surface position. The figure shows that eighteen crossbeams/or crossbeams on the floating pontoon bear the weight of the entire main section with the console and in this case the excavator. At the top of the lift tower there are holders for anchoring the main section's top part during transport. In this position, however, the construction can also be used to carry out various works, as is evident from the figure. The construction is supported so high up in the pontoon that the turntable for the excavator is above the deck, which means that the working angle is approx. 90°, somewhat depending on how far the console is from the end edge of the pontoon. For transport, the construction can possibly be lowered further down, e.g. by moving the cross beam further down or using other support means, so that you get better stability during transport.

The main section 13 and the joint sections 12 can be provided with external and/or internal stiffening ribs or longitudinal frames. Three such ribs 72 are shown in fig. 2.

The one in fig. 1, the upper console slide 34 can, if necessary, be connected to the piston of a known per se hydraulic cylinder unit vertically arranged on the outside of the main section 13 for displacing the console in the vertical direction. Other lifting devices can possibly also be used.

Claims (7)

Work structure for carrying out work on the seabed outside the structure, of the kind that includes a mostly vertical pipe string in the working position or a pipe with a transverse dimension that is at least equal to that of a manhole and whose interior is in connection with the atmosphere, where the pipe string is arranged to to be lowered from and during the work to be in connection with an anchored pontoon, platform etc., as the upper part of the pipe string is designed to be held in a submerged position by the pontoon, characterized in that the lower end of the pipe string is made with a closed bottom (16) as on the underside has a gripping device (19) for fixing the pipe string in the seabed (3), and that the lower part of the pipe string on the outside is equipped with at least one vertically extending guide (33) and at least one work console (30) or outrigger, which can be pushed forward along the guide on the pipe string and which serves as a foundation for at least one working machine (36). 2. Construction according to claim 1, characterized in that the console (30) on the bottom side has at least one member (42) for engagement with the seabed. 3. Construction according to claim 1 or 2, characterized in that the console (30) carries a turning and storage ring (fig. 5) for rotatable storage of a work machine (36), e.g. an excavator, a drilling rig, a mud cleaner, etc. 4. Construction according to claim 1, 2 or 3, characterized in that the console guide (33) is equipped with a device known per se, e.g. jack or winch, for vertical movement of the console (30). 5. Construction according to claims 1-4, characterized in that the lower part of the pipe string consists of a separate pipe (13) with an enlarged cross-section in a manner known per se in relation to the upper part (12) and internally arranged as a maneuvering chamber (45) for the work machine (36). 6. Construction according to one of claims 1-5, characterized in that the lower part of the pipe string is made with a double bottom (16, 46) which forms a ballast tank (49). 7. Construction according to one of the claims 3-6, characterized in that the turning and storage ring is placed in a circular, horizontally divided housing with an upper part open at the bottom (39) which is rotatable in relation to the housing's stationary, on the console (30) attached lower part (35), and which housing is equipped with devices (60) for supplying a pressure medium that is lighter than water, e.g. compressed air or pressurized oil, and where the lower part (35) open to the top has a smaller diameter than the upper part (39) and includes outlet devices for the discharge of penetrated water and any pressure medium, to maintain a certain maximum water level in the house.