NO20092576A1 - Floating reef - Google Patents

Abstract

A floating reef comprises a group of tubes 110, 111 of different diameters fixed around each other in a frame 105. The reef is placed at the desired depth by anchoring 120 and buoyancy elements 150, 115. The reef forms an artificial habitat that attracts several marine species, and form a local ecosystem in marine areas where it is impossible or impractical to use substrates located on the seabed. The reef, when mounted and lowered to the desired depth, has a large surface and many cavities pervolumised. The pipes have different diameters and can be threaded together during transport. By using lightweight, mass-produced plastic pipes, a reef is obtained which is both attractive to a variety of marine species and at the same time easy and affordable to produce, store and transport. By hanging on flexible bands, the surface available for seaweed and kelp can be further increased easily.

Description

BACKGROUND AND KNOWN TECHNIQUE

This invention relates to a floating reef.

Modern farming facilities are in many cases an environmental burden. Large numbers of fish in an area with little water exchange can lead to a lack of oxygen. Uneaten feed and excrement can, in the worst case, feed algal blooms, which worsen the lack of oxygen. In Norway, there are entire fjords that are practically empty of fish and sea animals because of this. Areas inland are also heavily stressed, and for these and other reasons cages have been moved to deeper, but still coastal, sea areas with, among other things, greater access to oxygen.

It is still a problem that uneaten feed and excrement that fall through the slot in a cage are an excellent food source for wild fish, such as pollock. The wild fish will naturally stay by the cage, and will not get the exercise it would get in a natural hunt for food. The result is wild fish of less good quality. This can be a problem for coastal fishing, particularly in areas where there are many and/or large aquaculture facilities.

Farming facilities are also large monocultures that consume other resources and counteract biodiversity.

If an environment with richer flora and fauna can be provided around the farms, a number of these and similar problems can be solved. For example, greater biodiversity will be able to increase the amount of the sea area's natural forage production, for example as supplemental and stabilizing forage for wild fish that live around and eat waste feed from aquaculture facilities. An environment with a greater number of fish species will also make it possible to increase the amount of fishing via new fishing grounds for players with simple fishing gear.

A first task sought to be solved with the present invention is therefore to provide an artificial habitat that attracts organisms, several marine species and forms a local ecosystem in sea areas where it is not possible to use natural substrates/new substrates located on the seabed.

Because clams, shells, seaweed and kelp need surfaces to grow on, the habitat should have the largest possible surface area suitable for this purpose per unit volume.

Because some fish and other marine species thrive best when there is ample access to cavities and other hiding places, the habitat should have as many cavities as possible suitable for this purpose, also per unit volume.

In order for such a habitat to spread further, it is also important that both production and transport costs are kept low. It would therefore be an advantage if the elements are easy to manufacture, if the elements are easy to assemble into a habitat with a large area and many cavities, and if weight and volume are kept to a minimum during transport.

SUMMARY OF THE INVENTION

This task is solved by providing a floating reef, characterized by the fact that it comprises a group of pipes attached to each other.

The reef can be placed at the desired depth using anchoring in the seabed and floating or buoyancy elements. The reef should be placed deep enough so that waves and wind are not a big problem and at the same time shallow enough for a lot of sunlight to penetrate. The reef, when assembled and sunk to the desired depth, has a large surface and many cavities per unit volume, and will thereby form an artificial habitat that can attract several marine species, and form a local ecosystem in sea areas where it is impossible or impractical to use substrates placed on the seabed.

When the pipes have different diameters, they can be threaded into each other during transport. This saves volume, and thereby transport and storage costs. By using pipes made of suitable plastic material, weight is also saved. Reduced weight leads to further reduced transport costs. The tubes can be of a standard mass-produced commercial quality, which can also reduce production costs.

After installation and deployment, pipes with different diameters seem tempting to several different species. By hanging on flexible bands, the areas where seaweed and kelp can grow can be further increased in a simple way without significantly increasing production or transport costs.

Several embodiments appear from the attached set of requirements.

BRIEF DESCRIPTION OF THE FIGURES

The invention is described in more detail below with reference to the attached drawings, where like reference numbers refer to like elements and where:

Figure 1 is a schematic diagram of a floating reef

Figure 2 shows an embodiment seen from the end.

Figure 3 shows a reef where the floating elements are placed in the reef

Figure 4 shows an embodiment with flexible bands

Figure 5 shows pipes with different diameters which are threaded together and stacked

DETAILED DESCRIPTION

Figure 1 is a schematic diagram of a floating reef according to the invention. The reef consists of a collection of pipes 110 which are attached to each other, for example by means of frames 105, and sunk to a depth below the sea surface 200. In sheltered locations where the reef will not be exposed to particularly large surface waves or swells, i.e. where the significant wave height is small, it may be advantageous to place the reef close to the surface so that as much sunlight as possible penetrates down to the reef, whereby the production of biomass can be increased. Elsewhere, it would be more appropriate to lower the reef to a depth of, for example, 5-15 meters to avoid surface phenomena such as wind and waves, while allowing a sufficient amount of light to penetrate down to the reef.

In Figure 1, fixing of the pipes is illustrated with two frames 105 which are arranged across the longitudinal direction of the pipes. The frames are attached to an anchor line 120, which is in turn anchored to the seabed (not shown). The anchoring is greatly simplified if the reef is placed, for example, 2 x deeper than the significant wave height on the site, so that one does not need to take special account of the fact that the floating part will swing vertically and pick up wave frequencies at the system's natural frequency.

The reef can be kept afloat by a buoy 150 and/or air-filled tubes 115 as shown in Figure 3. The buoy 150 is intended to illustrate buoyancy or buoyancy outside the reef in general. Since the buoy 150 is optional (can be replaced with floating elements such as the tubes 115 in Figure 3), both the buoy 150 and its attachment are shown with dashed lines in Figure 1. Figure 2 shows an embodiment of a reef according to the invention seen from the end of cylindrical tubes 110, 111. The pipes are clamped in a rectangular frame 105 as shown in Figure 1, and the pipe 111 has an outer diameter slightly smaller than the diameter of pipe 110. The pipe 111 can thereby be threaded into pipe 110 during transport as shown in Figure 5. Figure 2 also shows that the space between the pipes will provide good hiding places and good escape opportunities, and will therefore be thought to be attractive to some species. The surface of the tubes 110, 111 will also provide attachment for eg seaweed, kelp, shells and other organisms needed in a marine ecosystem. Figure 3 shows an embodiment where two tubes 115 are sealed at their ends. When a volume of air is trapped in this way, the tubes 115 will provide buoyancy. This buoyancy can completely or partially replace buoyancy from the buoy(s) 150 shown in Figure 1. Figure 4 illustrates an embodiment with flexible bands 140. For simplicity, only one tube 110 is shown with two bands 140, but it is of course possible to provide flexible bands on pipes with other diameters, e.g. pipe 111 in Figure 2, and it is trivial to place as many bands as desired along the pipes. These bands 140 can increase the surface area available to seaweed, kelp, etc. without significantly increasing weight, volume or production costs. Figure 5 shows pipes with different diameters, e.g. pipes 110 and 111 from Figure 2, which are threaded together and stacked. As the artificial reef can be packed in this way, volume is saved, and thus costs, during transport and storage.

By using pipes made of suitable plastic material, weight is also saved. Reduced weight leads to further reduced transport costs. The tubes can be of a standard commercial quality that is produced in large quantities, which can also reduce production costs.

Claims (5)

1. Floating reef, characterized in that it comprises a group of pipes (110,111) attached to each other. 2. Rib according to claim 1, characterized in that the pipes (110, 111) have different diameters. 3. Rib according to claim 1, characterized in that it comprises flexible strips (140). 4. Reef according to claim 1, characterized in that floating elements (115) are placed in the reef. 5. Reef according to claim 1, characterized in that floating elements (150) are placed outside the reef.