FR2971397A1 - Artificial reef for juvenile and adult fish of sedentary species e.g. shellfish, has ecological box filled with soft sand or gravel, where box includes tapered ceiling at specific acute angle for generating narrow space of shelter - Google Patents

Abstract

Artificial reef for juveniles and adults of fish and crustaceans with ecological boxes (1) in particular for sedentary species with a shelter zone (4), an evolution zone (3) and an entry (2). Examples of structures are described.

Description

Description. The object of the present patent concerns the creation of artificial reefs for juveniles and adults of fish and crustaceans in particular sedentary and the structures which result from them. The profitability or productivity of artificial reefs is related to both the fish and crustaceans they attract but also to their ability to set high-value, sedentary species that are present almost year-round. Hence the interest of developing artificial reefs for all size classes of sedentary species. 1.o Artificial reefs for sedentary species are designed to generate ecological lodges or "habitats" in which each species will find a space of shelter, rest or look corresponding to its size and way of life. In the wild, sedentary species have the opportunity to escape into storm-protected areas, usually in steep, deep faults where wave energy is reduced. If these natural shelters not exposed to bad weather are relatively rare for adults, they are even rarer for the fry that frequent the shallow areas so more exposed. This makes the situation even more problematic for fry which, in addition to the effects of the storm, are subject to higher predation. In fact, these sedentary species must be provided shelter where, on the one hand, the action of the swell is attenuated and on the other hand spaces where they can hang by contraction against the walls (conger, grouper, mostelle , labre ... 2 octopus) and / or hang on the walls (scorpion fish, lobster, lobster ...). In general, the fish or crustacean, fry or adult, must find a suitable space for his body in all situations of rest, defense, watching, blocking during heavy swell or moulting for crustaceans . 3G The traditional artificial reefs generally offer cryptic spaces (faults) or lodges made up of parallel walls or too wide apart and not presenting a hook that does not meet the real needs of sedentary fish because they can not be blocked during periods of heavy weather or protect themselves by taking refuge in areas inaccessible to big 3.5 predators. . Thus, most artificial reefs are deserted during periods of heavy weather or do not provide effective shelter against predators. With regard to artificial reefs generating ecological spaces, there are a multitude of structures made by stacking plates such as the 40 structures protected by Tamura Shigeo's patents (Artificial fishbreeding reefs - JP2003219255), by O'Hare Christopher (Method for assembling artificial reef modular units - US2003138296), Clamagirand Etienne (Modular artificial reefs - W00177443), Jones Barton and Green Ray (Artificial reef modules - US5113792), Kimura Koichi (Artificialfish gathering - US4316431), Marinaro Jean Yves ( artificial reef system intended to create a habitat for fish populations - FR2737082) .... These horizontal stacks offer resting structures, temporary stays but no real shelters or habitats responding to a real behavior or to ethology target species. The aim of this patent is to refine these first achievements in Io proposing a new generation of reefs focused on the habitat of sedentary fish and crustaceans and their basic needs with respect to ecological lodges. The general principle of artificial ecological lodges (1) is to include areas with specific functions that meet the needs of fish and 1.5 crustaceans, namely, an entry (2) adapted to the size and shape of fish or crustaceans (juveniles to adults). ), a space (3) near the entrance allowing the evolution of the fish or crustacean (rotation, turning, forward / backward, observation, possibility of moulting without leaving the shelter) and finally a space of refuge (4) more narrow at depth, space of refuge against predators or shelter against the movements of water. The space (3) that can be considered as an antechamber, can have the lower walls (5) and upper (12) parallel or oblique provided that the volume generated allows the fry or the adult to evolve . This volume has been virtually imaged by dotted lines in particular in FIGS. 3, 4, 7 and 8. The space (4) will be the size of its occupant in the rest or refuge position (depth, height). To respond effectively to this structural problem, the space (4) will consist of walls positioned obliquely at an acute angle (x) preferably between 3 and 25 ° (Figures 1, 2, 3, 5 ...) depending on the species and size of the target fish and shellfish. The choice of the angle (x) corresponds to the shape of the species that will inhabit the boxes (1), the tail being narrower than the head or flanks more or less wide, the angle (x ') will be particular to case. The angle (x) can be represented with rectilinear (Figure 1) or curved (Figure 2) walls. The depth of the shelter part (4) of the box can generally be 50 cm, that of the evolution part (3) can be 30 cm. These measurements are given as an indication and can evolve. 4.0 The bottom wall (5) will be rough or meshed to allow species to attach by their legs or fins.

3 The axis (7) of meeting the planes of the walls generating the ecological box (1) preferably being in a horizontal position (Figure 3,4, 7) for crustaceans or vertical to mimic faults frequented by fish such as groupers, Corbs, sea bream or wolves. (Figure 5, 6, 8).

In the case where the axis (7) is horizontal (crustacean reef), the width of the ecological box (1) is determined by side walls that can determine individual or collective boxes (19) (Figure 14). In the case where the axis (7) is vertical (fish reef), the height of the box (1) is determined by the bottom and a ceiling of variable height.

The inlet can be partially closed by perforated outer or outer walls (8) and inner walls (8 ') to reduce the effects of water movements or provide an additional cover. For fry, the objective is to propose boxes responding to a multiplicity of sizes of fish and crustaceans ranging from 0.25 to 50g, often with a problem of closing the openings by "fouling" (Fixing animals or plants). To meet the need for a large number of different sized boxes and openings according to the criteria described above, juvenile reefs including sedentary fish and crustaceans are preferably developed with laminar structures (15) constructed from webs solid materials, semi-flexible flexible sheets or plastic mesh (Polypropylene or any other soft or semi-rigid material) or composite vacuum mesh materials of 1 to 5cm, 1m wide and 5 / 10m long . These standard coil sizes are given as examples and are not limiting in terms of size or mesh gap. The webs of these materials are coiled loosely (16) to generate spaces that can serve as lodges. The coils (16) thus produced generate ecological boxes (1) according to the stated principle with an acute angle (x), a refuge space (4), an evolution space (3) and a front opening (2). or lateral to the outside (2 ') (Figures 2, 6, 9, 10, 11, 12). In fact, the lateral opening of the space (4) towards the outside is generally quickly closed off by the "fouling" (fixation of plants or animals) 35 thus forming an outer wall and the exit towards the outside is made by the lateral part (2 ') of the space (3). The lamellar structures (15) based on plies of solid material or roasting can be conditioned in multiple ways, namely in the form of coils (16) loose more or less flattened (Figure 9), sets 4o horizontal folds ( 17) (Figure 10) or vertical (17 ') (Figure 11), rosette or half-rosette (18) (Figure 12). The rosette is made by folding the sheet and attaching the edges of one side of the fold.

The principle of construction being described, the lamellar structures developed in this document are not limiting. Retaining means such as ropes (30) or rods (29) passing through the structures are implemented as well as containers to immerse these different laminar structures and position them at the bottom. The containers can be advantageously replaced by using the free spaces of traditional artificial reefs to house the laminar structures (15). Holes (34) in the walls of the reef structures (33) are provided to position fixing rods (35) of the laminar structures (15) as a coil (16). (Figure 18). With regard to the realization of ecological boxes made of compact materials (concrete) according to the characteristics described above, the reef structures will be elaborated by stacking elements (9) preferably in rounded concrete (FIGS. 13 and 14) or parallelepiped (FIG. 15) having a planar and rough upper face (10), a lower face consisting of a flat central part (11) parallel to the upper face, extended outwards by a ceiling (6) preferably forming an angle acute (x) from 3 to 25 ° with the central part and an outer border. The ecological boxes thus produced by said elements (9) (plates) are composed on the one hand of a space (4) of shelter and shelters composed of a horizontal floor (5) and a ceiling (6). ) forming an acute angle preferably between 3 and 25 ° and secondly a space (3) of reversal or evolution consisting of the horizontal floor (5) with a horizontal ceiling (12) or oblique in the extension of the ceiling (6) in front of an opening (2) partially closed by one or more walls (8, 8 '') .The outer edge alternately has solid (8) or perforated (2) walls representing the entrances of the habitats. on the bottom plate on the base of the solid edge (8) as well as on the central part (11) when the plates are round and (20) when the plates are parallelepipedic The plates can be embedded one inside the other by the intermediate cells located on their upper face, alv poles (13) réceptionnant 35 the central portions (11) or (20) and recesses (14) réceptionnant the edges of the outer walls (8). The ceiling (6) of the space of refuge (4) can go linearly with an angle (x) to the border (8), generating, in continuity, a sufficient space for the reversal function of the space (3) or may be extended by a horizontal portion (12) to the border (8). (Figure 13) The boxes are separated by side walls (19). (Figures 14 and 15) The fixing of the elements (9) is effected by means of threaded rods passing through the orifices (21) passing through all the elements (9).

To reinforce the colonization of these concrete habitat reefs (26), elements with a trophic function such as rods (31, 32) preferably made of composite materials are associated with the ecological boxes (1) in particular in extension of the latter.

The stems (31) located in extension of the ecological lodges (1) bring to the fauna "housed" an extension towards the outside of the lodge (1) and a food quota of proximity, food quota increased by rods (32) sealed over the entire surface of the structure (33) (Figure 18). Finally, obtaining an ecological box (25) according to Figure 16 may be 1 o achieved by the combination of a hard material ceiling (23) and the surface of the natural furniture base (24) and by means (27) to generate and maintain the angle (x). Observed in nature, it is a new concept of artificial reef construction in harmony with the aquatic environment (Figure 15). The space generated between the ceiling (23) and the bottom (24) has a narrow refuge area (4), evolution (3) and an entrance (2). The corresponding reef (22) comprises a planar portion (26) which will provide the oblique ceiling (23) in association with a portion (27) arranged perpendicularly to (26) generating the acute angle (x) between the ceiling (23) and the bottom 20 (24). At the end of the portion (27) are arranged anti-scouring elements (28) for holding the element (26) in an oblique position. Figure 1 shows the concept of creating an ecological lodge with two flat planes at an angle (x), Figure 2 along two curved planes. Figure 3 represents the concept of ecological lodge with its refuge zone (4), its evolution zone (3) having a ceiling (12) parallel to the floor (5) and its inlet (2). Figure 4 shows the evolution zone (3) with its ceiling (12) in line with that of the zone (4). Figure 5 shows an ecological box for fish with the wall meeting axis (7) in a vertical position, the dotted lines representing the separation of zones (3) and (4). Figure 6 is identical to Figure 5 but with curved walls. FIG. 7 represents a semi-apical view of an ecological box 3-5 notably for crustaceans with its shelter zone (4), its evolution zone (3), its entrance (2) and the entrance walls; (8) and inner (8 '), the angle (x) being in a vertical plane. Figure (8) is a semi-apical view of an ecological box including fish, angle (x) being in a horizontal plane. Figure 9 shows a laminar structure (15) in coil form (16). Figure 10 shows a structure made by a horizontal folding (17). Figure 11 shows a structure made by vertical folding (17 ').

Figure 12 shows a lamellar structure (15) in the form of rosette (18). FIG. 13 represents, in vertical section, a stacking structure of prefabricated plates (9) generating zones (3) and (4), bearing points of the plates one on the other by the center (11) and by the side walls (8). Figure 14 is an apical view in section a / a 'of a round-based reef structure, showing the outer walls (8), the inner walls (19), the shelter (4) and evolution areas (3) and the inputs (2). Figure 15 is an apical view in section a / a 'of a parallelepiped-based reef structure. Figure 16 shows the concept of an ecological box generated by a plate positioned obliquely at an angle (x) with respect to a soft or hard natural background. Figure 17 shows the reef structure (22) from Figure 16 with its plate (26) generating the ceiling (23), the plate (27) perpendicular to (26) and its scouring plate (28). Figure 18 shows the association of lamellar reefs (15) with a traditional reef (33) with holes (34) into which are inserted plugs (35) passing through the coils (16).

Figure 19 shows in section a reef structure (33) with its ecological boxes (1) associated with trophic rods (31) in their extension and with rods (32) distributed on the surface of the structure (33) . We will therefore remember that the ecological lodges (1) composing the reefs consist of flat or curved, flexible, semi-rigid or rigid walls, solid (sheets of plastic or concrete slabs) or openwork (mesh, lattice) or furniture (sand, gravel), positioned at acute angles preferably between 3 and 25 °, generating a narrow space (4) of shelter and blocking fish or crustacean associated with a wider space (3) of evolution located behind an inlet (2) partially closed by one or more walls (8) full or perforated. The present invention concerning new developments of ecological boxes of artificial reefs finds an obvious application in the development of future artificial reefs better adapted to sedentary species.

Claims (10)

CLAIMS. 1-- Artificial reefs for juveniles and adults of fish and crustaceans, in particular of sedentary species, characterized in that the ecological boxes (1) which compose them consist of flat or curved, flexible, semi-rigid or rigid, solid walls (plastic leaflets or concrete slabs) or openwork (mesh, trellis) or furniture (sand, gravel), positioned at acute angles preferably between 3 and 25 °, generating a narrow space (4) for shelter, refuge and blocking the fish or crustacean associated with a wider space (3) evolution located behind an inlet (2) partially closed by one or more walls (8, 8 ') full or zo perforated. 2 - Artificial reefs for juveniles and adults of fish and crustaceans, especially for sedentary species characterized in that the axis (7) of meeting the two planes generating the ecological box is preferably in a vertical or horizontal position. 15 3 - Artificial reefs made by stacking concrete slabs according to claim 1 and 2 characterized in that the upper and lower plates create ecological lodges composed on the one hand of a space (4) shelter and shelter composed of a preferably rough horizontal floor (5) and a ceiling (6) forming an acute angle preferably between 3 to 25 ° and secondly a space (3) of reversal or evolution composed of the horizontal floor (5) with a horizontal ceiling (12) or oblique in the extension of the ceiling (6) in front of an opening (2) partially closed by one or more walls (8, 8 '). 4 - artificial reefs made by stacking concrete slabs according to claim 1, 2 and 3 characterized in that the upper plates of cylindrical shape or parallelepiped shape, fit on the lower plates in adapted cells (14) at the lower parts of the borders (8) and the cells (13) adapted to the central parts. 5 - Artificial reefs for juveniles and adults of fish and crustaceans according to claim 2 characterized in that they are made by plies of solid materials, flexible semi-rigid leaflets or mesh of plastics or composite materials wound with loosely in the form of coils (16) and held in shape by ropes (30) and / or fixing rods (29). 35 6 - Artificial reefs according to claims 1 and 2 characterized in that they are made by zigzag fold (17) of the mesh or sheet web and held in shape by ropes (30) and / or fixing rods (29). 7 - Artificial reefs according to claims 1 and 2 characterized in that they 4 o are in the form of rosettes or half-rosettes (18) made zig-zag folding of the mesh or sheet of sheet, a link connecting one of the edges of the fold and held in shape by ropes and / or fixing rods. 8 - artificial reefs according to claim 1 characterized in that the ecological boxes 5 are made by the combination of a ceiling (23) of hard materials and a soft or hard natural bottom (24), the acute angle (x) being obtained by the combination of the flat portion (26) generating the ceiling (23) with a portion (27) perpendicular to (26) and provided with a portion (28) against scouring. 10 9 - Artificial reefs according to claims 1, 2, 5, 6 and 7 characterized in that the structures made from materials in the form of sheet or mesh are positioned in the empty spaces of traditional reefs (33) concrete and fixed by rods (35) stuck in holes (34) of the reef (33). 10 - artificial reefs according to claims 1, 3 and 8, characterized in that L5 trophic function elements such rods preferably made of composite materials, are associated with the ecological boxes, including an extension of the latter (31) or a more generalized (32) over the entire surface of the reef (32).