NO754395L - - Google Patents

Description

Construction for the deposition of sediment at the bottom of a water area.

The invention relates to a construction for the deposition and protection of sediment that is transported at the bottom of an ocean, a lake, river or other water area.

In addition to coastal protection, the construction can be used for e.g. prevention of siltation of sailing ends and harbor estuaries.

A third area of application is protection against undermining and damage by ship anchors and fishing gear to elongated underwater structures such as pipelines, cables, foundations and the like. In this case, the structure is placed on top of or to the side of the structure to be protected.

It thereby causes a deposit along its sides and protects it directly against ship anchors and fishing gear.

In Norwegian patent application no. 7M1656 is described

a method and corresponding construction consisting of an elongated surface which along the middle is raised above the level of the bottom

so that the cavity below the surface can be filled up by the sediment brought in by waves and currents.

For economic reasons, it is desirable that the structure can be prefabricated on land and then floated to the place where it is to be installed so that the diving work is minimal. But if the construction is made of a heavy material such as e.g. steel or concrete,' e.g. with a view to great resistance to damage from ship anchors and fishing gear, the construction's weight becomes so great that it becomes impractical for divers to handle.

The present invention provides

therefore a construction that contains caverns so that buoyancy can make the construction weightless underwater.'

When the construction is in place, the cavities can be filled with water so that the construction achieves the greater weight that is then desired.

By means of the construction according to claim 1 up-

a sediment-depositing structure is reached which is not damaged by ship anchors and fishing gear and which during the installation work can be made weightless under water and which can then achieve such a weight that there is no need for anchoring in the bottom or other fixing.

With the rounding according to claim 2, it is achieved that the formation of turbulence is minimal and the deposition thereby maximal.

The design according to claim 3 prevents undermining of the lower edges.

The design according to claim 4 prevents the ship's anchor and fishing gear from damaging the structure.

The construction material concrete according to claim 5,

is particularly suitable because it is corrosion resistant, strong and castable.

The reinforcement according to claim 6 enables the concrete to absorb all the occurring forces.

The alternative designs according to claims 7 and 8 together cover the commonly occurring cases.

The design according to claim 9 can be appropriate for achieving greater weight of the water-filled construction.

With the design according to claim 10, an interlocking of the elements is achieved in a simple way.

With the help of the alternative designs according to claims 11, 12 and 1H, it is achieved that the weight of the elements underwater can be regulated as needed so that divers can handle the elements.

Re-use according to claim 13 reduces the output.

The dimensioning according to claim 15 made such protection of a pipeline or a cable an ethereal alternative to the costly burying or flushing of the pipeline or cable.

By means of the alternative designs according to claims l6,17,l8 and 19, it is avoided that the anchor or the fishing gear becomes stuck around a pipeline or a cable that is protected by the construction.

With the design according to claim 20, it is achieved that an anchor which is towed across the construction will more easily "walk" above the construction without taking hold of its lower edge.

The correction of the structure according to claim 21 increases its strength and stiffness.

With the design according to claim 22, great strength is achieved, partly a minimal turbulence formation at the top of the structure, and partly great soil resistance against lateral displacement.

By means of the tension bands described in claim 23.

a strengthening of the construction is achieved.

Under certain local conditions a

savings by means of the design according to claim 24.

With the fixing method specified in claim 25, it is achieved that the structure can be mounted on the structure above water and swung into place when the structure is placed on the bottom.

In the design according to claim 26, part of

or the entire protective structure is saved.

In the method according to claim 27, it is achieved at least

possible total expenditure.

In the following, the description will be related

to the drawing where

fig.l is a plan view of a concrete element with a horizontal underside, inclined end surfaces 19, 20, 2.1 and 22, spring 23 and groove 24., flow openings 68, barbs 69, and cavities 58,

fig. 2,3 and 4 are cross-sections on an enlarged scale along the lines XII-XII, respectively. XIII-XIII and XIV-XIV in fig. 1,

fig. 5 is a plan view of elements for the protection of a pipeline 15; the elements contain cavities 58 and are divided along the middle into symmetrical halves 6l or 62 and assembled in pairs over the pipeline by means of fittings 59,

fig. 6 and 7 are alternative longitudinal cross-sections

the line XV-XV in 'fig. 5,

fig. 8 is a cross-section of a construction provided with cavities 58 for the protection of a pipeline or a cable 15 where the individual elements are spanned across the pipeline or cable from one longitudinal edge to the other,

fig. 9 is a cross-section of an element for coastal protection, provided with tension bands 45,

fig. 10 is a plan view of the foundation of a

special type of drilling platform,

fig. 11 and 12 are alternative longitudinal cross-sections

the line XVI-XVI in fig. 10.

The construction's cavity 58 can be larger or smaller and arranged in different ways.

In most cases, a closed system of interconnected channels will be most practical. The regulation of the system's air or water content takes place between one or more channels that connect the system to the environment and is regulated with valves or plugs.

At very shallow water depths, the channels may possibly be open at the bottom without interconnection and without the use of valves. E.g. can the channels in a concrete element as shown in fig. 6 or 7, be parallel and perpendicular to the pipeline 15, be closed at the upper end at the top of the pipeline and be open below at the lower edge. As the water pressure at such a small water depth is very small, it will not significantly compress the air in the channels. By lifting the lower edge of the individual element, the channels can be filled with water when the element is in place.

If the construction material is concrete, the voids can be made up of interconnected, evenly distributed pores that can appear during the production of the concrete as lightweight concrete.

so that the concrete is water absorbent. In order to avoid other absorption in the pores should the construction be in place, the surface of the element can be made of waterproof concrete in which through one or more channels the porous interior connects with the surroundings so that the water content can be regulated by means of valves.

The surface of the porous concrete can also be covered with a waterproof cover of e.g. plastic. When the element is in place, the cover is removed so that the pores can be filled with water.

In addition to the deposition of sediment, the described construction is suitable for protecting a pipeline, a cable or the like against damage from the ship's anchor and fishing gear.

In many cases, an anchor and in any case a fishing gear such as a trawl boom that is towed across the structure will slide over it without getting stuck in it. To avoid, as far as possible, the anchor or trawl boom getting stuck in the lower edge of an element, the edge can be made wavy in the horizontal plane and/or in the longitudinal, vertical plane.

However, even if an anchor were to grip the lower edge of an element, the construction will still prevent the pipeline or cable from being damaged.

Firstly, it is not certain that the anchor is able to move the water-filled element, which may have a large length and a large weight per m 2. Even the end surfaces of the elements 16,19,20,21 and 22 (fig. 1,2,3,4), 66 (-fig. 5) can be bevelled and possibly provided with springs 23 and grooves 24 (fig. 3,4) or in some other way are made coherent so that all the elements together act as a unified whole.

If the anchor should still be able to move a. or several elements, the further progress depends on whether the elements span across the middle from one side to the other (fig. 1,2,8) or are divided along the middle into symmetrical halves (fig. 5~7) •

In the first case, the element or elements in question will, after a somewhat horizontal displacement, encounter such great earth resistance that they tilt up on the edge on the opposite side in relation to the edge on which the anchor is fixed, thereby lifting the anchor up over the pipeline or the cable.

To promote this tilting of the element, this can be equipped on the underside with barbs that stick into the bottom and increase the soil's resistance to the horizontal displacement. The anti-hooks can consist of protrusions on the underside of the element or of hoops or bars 69 (fig. 1,2), which can be pre-mounted on the element or mounted through holes after the element has been placed.

The aforementioned soil countersand can also be achieved with elements whose lower edges are wavy. The longitudinal direction of the waves is perpendicular to the longitudinal direction of the structure and the wave height decreases uniformly from a maximum at the edge to 0 some distance up

the side surface so that the top of the structure is. without correction. If the element is displaced horizontally, the wave valleys will be filled with sediment and need ever longer nea at the bottom.

In the case of symmetrically divided halves of the element (fig. 5~7), the fittings 59 can be designed with a hook at both ends which fits into corresponding recesses in the underside of the elements. If the ship anchor is able to move one

or more elements, they will slide out of the fittings and onto

the pipeline and thereby carry the anchor over it.

Por to ensure that the anchor is lifted that high

above the pipeline so that its arms do not hit it, the elements on the underside can be provided with sliding brackets or rods 72 (fig. (6)) which will force the elements further upwards during the passage of the pipeline.

Alternatively, stoppers, e.g. in shape

of hoops or bars 70' (fig- 7) at the meeting with the pipeline cause . a rotation of the element half around the axis of the pipeline. If the elements on the upper side are provided with correspondingly placed protrusions 71 (Fig. 7), it will then be possible to induce a rotation of the element half around it. original top edge when it hits the protrusions 71-

This lifts the opposite edge with the anchor in it

an arch up above. the pipeline. Instead of the protrusions 70 and 71, a similar effect can be achieved by means of ropes or chains which connect the upper edges of each pair of element halves to each other. The ropes or chains must be so long that the upper edge of the element half in which the anchor has stuck reaches more than halfway down the upper side of the opposite half before the ropes or chains are stretched out and causes the aforementioned rotation of the • first-mentioned element half. Until then, the excess length of the ropes or chains is placed below the surface of the structure.

In certain cases, an underwater structure only needs protection on one side. If e.g. a pipeline crosses a river where the current direction never changes, and where the wave motion at the bottom is insignificant, the element halves on the downstream-) side- of the pipeline can in some cases be omitted.

When prefabricating the element, its length is determined, among other things, based on considerations of whether one should strive for the greatest possible weight and thereby resistance to the ship's anchor and fishing gear, or the most convenient and cheapest possible repair work in the event of damage due to the anchor and the gear .

In the former case, the length is made so large

as construction, manufacturing and transport considerations allow, possibly up to several hundred meters or more. Here, the fastest and cheapest possible installation of the elements is achieved at the same time.

In the latter case, the length is adjusted so that each element or element half underwater can be handled by two divers.

When the task is to protect e.g. foundations for certain offshore constructions against undermining, it is most appropriate to mount the element halves 67 on the foundation (fig. 11) before launching. If they e.g. are attached with hinges, they can be transported on the foundation to the installation site in an open position and then swung down on the bottom after the placement of the foundation.

With a view to reducing the required width of the element half, the edges of the foundation should be cut so that the surface of the foundation completely (fig. 12) or partially (fig. 11) forms the desired contour in advance.

Claims (27)

1. Construction for the deposition of sediment on the bottom of a body of water, consisting of an elongated surface which along the middle is raised above the level of the bottom and possibly provided with flow openings, and whose longitudinal side surfaces have flat or domed upper sides, with the bottom forming opposite, directed slopes of magnitude 1-5 - 1-2, characterized in that the structure contains cavities whose content of air or water can be regulated with a view to adjusting the weight of the structure before and after its placement. 2. Construction according to claim 1, characterized in that the top of the construction is rounded. 3- Construction according to claim 1 or 2, characterized in that the angle of inclination of the side surfaces in relation to the horizontal gradually decreases towards the longitudinal edges. 4. Construction according to claim 1,2 or 3/ characterized in that its upper side is free of edges and unevenness that the ship's anchor or fishing gear can grip. 5- Construction according to any of the preceding claims, characterized in that it is made of concrete. 6. Construction according to claim 53, characterized in that the concrete is reinforced with steel, fiberglass or similar material with high tensile strength. 7. Construction according to any one of the preceding claims, characterized in that it is composed of interlocking elements which span from one longitudinal edge to the other. 8. Construction according to any of the preceding claims for the protection of underwater structures, characterized in that it is composed of interlocking elements which are divided along the ridgeline into interconnected, symmetrical halves and are supported on the structure it is to protect. 9- Construction according to any one of the preceding claims, characterized in that the lower sides of the two side surfaces have a weaker slope than the upper sides. 10. Construction according to any one of the preceding claims, characterized in that the interlocking of the elements is achieved by means of oblique cut-offs, as well as any tongue and groove in the end surfaces of the elements. 11. Construction according to any one of the preceding claims, characterized in that each element contains a closed system of interconnected channels which are connected to the surroundings through one or more channels provided with plugs or valves for regulating the system's content of air or water. 12. Construction according to any of the preceding claims, characterized in that the interior of the construction is made of water-absorbing lightweight concrete, while the surface consists of waterproof concrete, and that the interior of the construction is connected to the surroundings through channels that can be regulated by using plugs or valves. 13. Construction according to claim 11 or 12, characterized in that the valves are removable and can be used again. 14. Construction according to any one of claims 1-11, characterized in that it is made of water-absorbing lightweight concrete which, during the installation work, is covered by a removable waterproof cover. 15- Construction according to any of the preceding requirements, characterized in that the individual element is dimensioned to bear the weight of a ship's anchor or fishing gear, also in the situation where the anchor or gear has displaced the element from its original position. l6. Construction according to any of. the preceding requirements, characterized in that the individual element on the underside is provided with protrusions. 17. . Construction according to claim 16, characterized in that the protrusions have the form of downward-directed rods or plates that protrude into the bottom material. 18. Construction according to claim 16, characterized in that the protrusions have the form of downwardly directed hoops or rods which can possibly be attached after the placement of the element. 19- Construction according to claims 8 and 18, characterized in that the hoops, or the rods are positioned so that they cause detachment and displacement of element halves on one side of the structure on one side of the structure by one of the ship's anchors or fishing gear, which will cause a rotation of these halves and a lifting of the anchor above the structure or the tool. 20. Construction according to any of the preceding claims, characterized in that the contour of the construction's lower edges is wavy in a horizontal and/or vertical plane. 21. Construction according to any one of the preceding claims, characterized in that the side surfaces are wavy. 22. Construction according to claim 21, characterized in that the wave direction is perpendicular to the construction's longitudinal direction, and that the wave height gradually decreases from a maximum at the construction's lower edges to 0 in the direction towards the back. 23. Construction according to any one of the preceding claims, characterized in that its lower edges are connected by horizontal stretch bands across the longitudinal direction of the construction. 24'. Construction according to any of the preceding claims for the protection of an underwater structure, characterized in that the downstream half of the construction is omitted. 25- Construction according to claim 24, characterized in that the upstream half of the construction is in a pivotable hinged connection with the structure. 26. Construction according to any of the preceding requirements for the protection of an underwater structure, characterized by the surface of the structure being designed as part of the structure's surface. 27. Method for placing the structure according to any of the preceding claims, characterized in that the structure is prefabricated in elements of the greatest possible length on land and then floated to the place where they are to be lowered and placed.