FR2913033A1 - Anchorage device for attaching e.g. shoreline signpost in ship, has attaching unit connected with anchorage line, and blade presenting evaluative pitch in screwing direction according to longitudinal direction - Google Patents

Abstract

The device (1) has a rod (2) extending according to a longitudinal axis (X), where the rod comprises helical surface i.e. helical blades (3), that are screwed in a sea bottom. The blade comprises an upper end (3a) and a lower end (3b) radially extending with respect to the rod. An attaching unit such as loop, ring or buckle, is arranged to an end of the rod and projecting to outside of the sea bottom, where the attaching unit is connected with an anchorage line. The blade presents an evaluative pitch in a screwing direction according to a longitudinal direction.

Description

The present invention relates to an anchoring device for mooring

  floating bodies, such as ships, and in particular an anchoring device, which is non-destructive of the seabed, especially those composed of Posidonia seagrass, and removable from said seabed, also non-destructively. Anchoring devices can be used to moor beacons, such as shoreline beacons, harbor beacons, safety beacons, chests, for example for naval vessels, navigation channel buoys , fires, floating anchor docks for ships, work barges, for example for fish farms, floating pontoons, or drilling rigs. In known manner, there are two categories of anchorages: temporary anchorages (anchorage) and permanent / semi-permanent anchorages. Permanent or semi-permanent anchoring can not be moved easily. It most often corresponds to a very heavy body placed or buried on the seabed. A provisional anchor is usually an anchor stored on a ship that can be thrown at sea and reboarded depending on the desired navigation. This system works by penetration and hooking of the anchor in the seabed. However, the seabed, especially the Mediterranean Sea, are made up of many varieties of plants, such as the posidonia meadow (Zostera marina). This flowering plant, which only exists in the Mediterranean, represents not only a habitat, a food source and a breeding area for many species, but also a significant source of oxygen for the ecosystem. In addition, it helps to stabilize the seabed and reduce beach erosion. This is why this species is protected. However, this plant, which grows slowly (lcm / year), is very fragile and is threatened by the anchoring of ships or floating bodies, whether temporary or permanent. Indeed, an anchor works by opposing the force exerted by the floating body attached to it, such as a ship. The forces exerted on the anchorage are thus due to the waves, currents, but especially to the wind which is exerted on the structure of said ship. By

  Therefore, under the combined force of the waves, the wind and the current, the ship can rotate a few degrees to 180 (reversing currents) around its anchorage point and thus sweep and thus sterilize, on a zone, so-called circle of evasion, the seabed.

  Anchoring will thus have the direct consequence of tearing off the roots and stems of aquatic plants, particularly those of the Posidonia meadow, and as a consequential consequence of having an adverse impact on the fauna and flora. However, the regeneration of the herbarium is too slow to compensate for these uprooting.

  In addition, there exists in the seabed of the Mediterranean, a green alga of tropical origin, accidentally introduced by humans in the region: the Caulerpa taxifolia. This alga, known as the killer alga, has become an invasive species because of its toxicity to the fauna due to the presence on the seaweed of several terpenes intended to protect it from herbivores, its negative impact on the biodiversity , and its worrying speed of development. Indeed, because of its highly invasive appearance, Caulerpa taxifolia may eliminate other species of marine flora. It threatens in particular posidonia meadows. In addition, the disappearance of the flora would also cause the movement of wildlife to uncontaminated areas. Thus, an anchor thrown in an area invaded by Caulerpa taxifolia would increase the risk of recovery (for example, by dispersing a dozen cuttings) and banalization of the seabed by this invasive algae. In order to protect coastal and island sites, particularly in the Mediterranean, protective measures have been taken. Decree 91-1110 of October 22, 1991 specifies, in particular in its article 13, that the equipment and installations established by the holder of the authorization on the zone of anchorage and the light equipments or used for its exploitation must be demolished at the end. of the authorization and the places delivered in the state. According to the prior art, various types of permanent or semi-permanent anchors exist to maintain a floating body, such as a ship. The anchor must not only keep the ship in all circumstances including during storms, but also be able to be

  3 easily detachable, for example to tow in a port a beacon for its maintenance or to defuse a ship. Permanent anchoring can be carried out in known manner by means of a dead body. The latter usually consists of a concrete slab or a heavy object, placed at the bottom of the water and connected by a rope or a chain to a buoy so that the boats can moor there. This technique has the disadvantage of being difficult to remove, to be polluting and to damage the seabed.

  The document FR 2 444 755 describes an anchoring device in a sea floor comprising a tube, subjected to an axial force and provided with one or more helically shaped portions arranged discontinuously on said tube, each of the forms being not constant and extending approximately one turn. Injection ports of a curable liquid soil reinforcement are provided on said tube and arranged in the direction of the axial force, traction or compression, applied to said tube. However, this anchoring system does not prevent the removal of said device upward, that is to say, it does not have sufficient resistance to tearing. Thus, this type of system may damage the flora and may not comply with the regulations in force. In addition, a cylindrical rod provided with a helical ramp, capable of being anchored in a seabed by screwing and further comprising on its upper part a ring for anchoring and transmission of screwing forces and unscrewing, is known according to document FR 2 503 657. Such an anchoring system proves to be destructive for the plant species present on the sea floor. Indeed, sediments are inserted between the helical turns, harden and subsequently form a core with said anchoring device which will also be removed during removal of the anchor. Thus, when the mooring area is removed, as provided by the decree, the installation area can not be restored.

  EP 0 947 420 describes an anchoring device and a method of anchoring underwater in a posidonia meadow.

  4 The anchor as described in this document is composed of a helical winding of a height of a few meters, consisting of a rigid wire (like a spring). However, as indicated in application EP 0 947 420, the posidonia meadow does not constitute loose soil. In fact, the Posidonia meadow corresponds to a dense network of rhizosomes and roots over a thickness of several meters, which prevents access to the underlying soil. However, with the anchoring system as defined in document EP 0 947 420, the dense network of rhizosomes and roots surrounds and invades, as and when it develops, the helical winding of the anchor, forming there too a carrot. Thus, such an anchoring device does not allow during its uninstallation, to make the natural environment intact, without locally tearing the herbarium. The present invention aims to propose a new anchoring device that avoids all or part of the aforementioned drawbacks. The present invention also aims to provide a new anchoring device adapted to be installed and fixed in a non-stable soil, such as mud. For this purpose, the subject of the invention is an anchoring device intended for a permanent and / or semi-permanent wetting line, comprising a rod extending along a longitudinal axis X, said rod carrying: at least one surface helically shaped, said helical blade, said blade being intended to be screwed into a seabed, and having an upper end and a lower end extending radially relative to said rod, - a fastening means, such as a eye, a ring or a loop, disposed at one end of said rod and intended to project outside the seabed, said attachment means being intended to be connected to said anchor line of said anchoring device, characterized in that said at least one blade has an evolutionary step in the direction of the screwing in the X direction. Such an anchoring device has the advantage of overcoming the problem of anchoring small and large structures floating, while preserving the seabed during its installation or uninstallation. Advantageously, said blade has a nominal pitch substantially constant with the exception of a first sector extending from the upper edge and having a substantially zero pitch. Preferably, said blade further has a pitch variation sector, having a decrease of said pitch with respect to a nominal pitch followed by an increase to return to the nominal pitch, so as to create on the surface of the blade a sector concave. According to a first characteristic, the first sector extends over at least 60.

  According to a second characteristic, the pitch variation sector extends over substantially 90 and is positioned substantially between the radii located at 180 and 270 from the upper end of said blade. Advantageously, the radius of the blade is substantially constant.

  According to one embodiment, the blade is produced by deformation of a plane metal plate in the form of a split disc along one of its spokes. Preferably, the pitch of the blade is in the order of magnitude of the radius of said blade and the pitch on the pitch variation sector passes through a minimum of 0 and a maximum equal to twice the nominal pitch. Advantageously, said anchoring device comprises several helical blades arranged along said rod in a discontinuous manner, so as to form a discontinuous helical spiral.

  Preferably, said anchoring device comprises an anchor blade, called a primer blade, of radius less than or equal to that of the other blades and arranged at the lower part of the rod so as to ensure piercing said seabed, and to facilitate the depression of said anchoring device at the desired level.

  The invention will be better understood, and other objects, details, features and advantages thereof will appear more clearly in the following description of a particular embodiment of the invention, given solely for illustrative purposes and not limiting, with reference to the accompanying drawings.

  In these drawings: FIG. 1 represents a general view of the anchoring device according to the present invention; FIG. 2 represents a perspective view of an embodiment of a blade of said anchoring device according to the present invention; - Figure 3 shows a developed edge of the blade as shown in Figure 2; FIG. 4 represents the figure of a disc before deformation by press, in particular showing cutting along a radius; - Figure 5 shows said anchoring system according to the present invention within a wetting device. In Figure 1, an anchoring device 1 according to the present invention for a wetting line 20 (Figure 5) permanent and / or semi-permanent is illustrated. This figure is a general view and does not represent all the distinctive features of the anchoring device 1 according to the present invention. However, as illustrated in this figure, the anchoring device 1 according to the present invention comprises a rod 2 extending along a longitudinal axis X, on which are fixed several helical portions 3, subsequently called blades and a means 4. Said rod 2 is straight and has two ends: an upper end 2a and a lower end 2b, the upper end 2a being close to the attachment means 4. This rod 2 has at its upper end 2a a straight cut, so as to form a flat surface, while the lower end 2b is cut at an angle of 45. This last characteristic makes it easier to penetrate into a seabed 21 (FIG. 5), whereas the right cut of the upper end makes it easier to weld rings or other attachment means. Said rod 2 can be made of rolled or drawn steel made of carbon or stainless steel. It can have a diameter ranging from about ten millimeters to several hundred millimeters and a length of the order of 1 meter to about 2.5 meters depending on the type of anchoring desired.

  Said attachment means 4 has the function of attaching said anchoring device 1 to one of the elements of the wetting line 20, such as a chain or a cable, itself connected to a semi-flooded floating object, such as than a buoy. Thus, this attachment means 4 is arranged to protrude on the seabed to hook said mooring line. This attachment means 4 may be for example an eye, a ring, a loop or a U-shaped bar or any equivalent means. As shown in Figure 1, the rod 2 also carries three blades 3. These blades 3 are intended to be screwed into a seabed 21. They generally extend either on less than one turn, or preferably on approximately at least one turn of said rod 2, the pitch of the blade 3 being of the order of magnitude of the radius of said blade 3. For example, for a pitch between 100 and 200 mm, such as of the order of 160 mm, has one for a radius of 200 mm. It is also possible, as illustrated in Figure 1, that said anchoring device according to the present invention comprises several helical blades 3 arranged along said rod discontinuously. This feature avoids much of the coring phenomenon. Advantageously, the distance between two consecutive blades 3 is between 300 mm and 800 mm. Each of the blades 3 of substantially helical shape has an upper end 3a and a lower end 3b, these ends 3a, 3b extending radially relative to said rod 2. The characteristics of said blades 3 according to the present invention will be shown in detail here. below, with reference to FIGS. 2 and 3. FIG. 2 illustrates a perspective view of a blade 3 of the anchoring device 1 intended for a wetting line 20 according to one embodiment. As is illustrated in this figure, the blade 3, although of helical shape, has an evolutionary helical pitch along the X axis and in the direction of screwing of said anchoring device in the seabed 21. In fact, each said blades 3 according to the present invention has various sectors of different helical pitch, more exactly 4, which we will name later: sectors A, B, C and D.

  First, the sector A extends from the upper end 3a of the blade 3 and is characterized by a substantially zero pitch over at least 50 to 60 of said blade. As shown in FIG. 3, the zero helical pitch can extend to 90. Thus, the blade according to the present invention has a first sector A perpendicular to any traction that may be exerted on said anchoring device. This feature has the advantage of providing a so-called stopper effect and therefore to ensure a good tear resistance of said device facing traction.

  Sector B also extends to 90. It presents a constant step, which we will call nominal in the following description. This nominal pitch corresponds to a propeller of conventional type, that is to say to a propeller having a constant pitch. The pitch of the blade at sector B thus merges with that of a conventional propeller, represented by dashed lines in FIG. 3. The sector C which extends over approximately 90 and is positioned substantially between the spokes located at 180 and 270 of the upper end 3a, is divided into two subparts, named C1 and C2. These two sub-parts are separated by a change of the value of the helical pitch, which we will call later break. The subpart C1 which follows the sector B in the direction of screwing the blade into the seabed as shown in Figure 4, is characterized by a decrease of the helical pitch extending over about 40 (Figure 3).

  The subpart C2 following subpart C 1 at the break, corresponds to an increase in helical pitch extending over about 50. This second sector C2 associated with the sector C 1 creates on the surface of the blade a concave surface. This concavity has the advantage of ensuring a suction effect and provide, combined with the effect of the sector A, good resistance to pulling in muddy soil. This can be explained by the suction effect that can occur when said anchoring device is pulled upwards, that is to say during traction exerted for example by the load moored to the mooring line.

  As shown in Figure 3, the sector D which follows the sub part C2 in the screwing direction of said device also extends substantially 90, between the radii located at about 270 and 360. This sector D is characterized by a nominal helical pitch. As is illustrated in FIG. 3, the pitch of the blade according to the present invention merges with that of a conventional propeller at sector D. Consequently, the shape of the sector D has the advantage of making it easier to penetrate the anchoring device 1 in said seabed 21. Advantageously, said anchoring device 1 comprises an anchor blade, called a primer blade (not shown), of smaller size than the other blades and arranged in the part lower of the rod so as to ensure the drilling of said seabed, and to facilitate the depression of the anchoring device at the desired level. When the device comprises a leader blade, the distance between said leader blade and the blade immediately above is between about 50 mm and 150 mm. In an alternative embodiment, it is possible that said anchoring device 1 as described above also comprises at least one blade with constant pitch. Thus, said anchoring device may comprise in the direction X and in the direction of screwing of said anchoring device 20 in the seabed 21, at least one blade 3 having an evolutionary step as described above, at least one constant pitch blade and possibly a primer blade, preferably at a constant pitch, to facilitate the screwing of said device into the seabed 21. The manufacture of an evolutionary step blade 3 according to the present invention will now be described Referring to Fig. 4. In order to provide a blade suitable for the present invention, it is preferable to start from a disk-shaped plate and deform it by cold forging. This disc is preferably made of stainless metal, such as a rolled or drawn steel composed of carbon or stainless steel. Said disk generally has a thickness of the order of 1 mm to 5 mm, the thickness being a function of the type of anchoring desired, the nature of the bottom, the size and the weight of the floating unit. In order to facilitate the realization of said blade, it is preferable that said disk has a constant radius R.

  The radius R of said disk suitable for the present invention may vary between 100 and 500 mm and more particularly, the disk has a radius R of between 100 and 300 mm when it comes to making a primer blade. In general, the size of the disk depends on the type of anchorage desired, the nature of the bottom, the size and the weight of the floating unit. For example, the radius R of the disk may be of the order of 204 mm with a thickness of 4 mm. In order to manufacture a blade, a radial slot 5 is first made to form a central orifice 6. In a first section, the disk is not deformed, so as to obtain a substantially flat surface, perpendicular to the axis X, which will have a helical pitch close to 0 out of 90. On a second section, the disk is deformed so that it takes a helix shape with a determined pitch (nominal) and substantially constant, also on 90. In the vicinity of the middle of the helix, a decrease of the pitch is caused on about 40 -50, followed by an increase on 40 -50. Finally, a return to the nominal pitch is caused locally on the last quarter turn of the propeller. At the end of this step, a blade with an evolutionary helical pitch is obtained. The embodiment for deforming such a disc is well known to those skilled in the art. It can be deformed by means of an oil press between two dies or cold forged. These techniques are well known to those skilled in the art and will not, therefore, not more detailed in the present application. Then, the fixing system of the blade or blades 3 and the attachment means 4 is usually by welding. It can be achieved by basic welding, that is to say by inert gas welding (MIG) or by inert gas tungsten welding (TIG). The installation of said anchoring device 1 and its attachment to a permanent and / or semi-permanent wetting line will now be described with reference to FIG. 5. The anchoring device 1 is preferably installed at low tide. in the seabed 21. In this case, it can be screwed by one or more people via a cross-shaped manual key containing the fingerprint of the fastening means 4. Said anchoring device 1 can also be installed outside tidal areas. In this case, said device is installed by one or more divers. The latter can screw said device 1 with a wrench mounted on a pneumatic screwdriver. In both cases, said device 1 is screwed so that the attachment means 4 protrudes from said seabed.

  As illustrated in FIG. 5, said wetting device 20 in a seabed 21, also called a wetting line, comprises the anchoring device 1 according to one of the preceding characteristics which is connected, thanks to its fastening means. 4, to a first section 23. The first section 23, which may be a chain or a cable is itself connected at its other end to a submerged float 24. In an alternative embodiment, it is possible that the device of anchoring 1 is connected to several first sections 23 of a wetting line 20 via a connecting bar when said wetting line 20 is composed of several first sections 23.

  In both cases, it is important that the first section 23 and possibly the connecting bar are permanently tensioned by the submerged float 24. The submerged float 24 is provided at its other end with a fastening means 24a, such as a loop, a hook or a ring or a shackle, said float having sufficient buoyancy to prevent any contact of the elements of said first section 23 of the wetting line 20 with said seabed 21. Said wetting device 20 also comprises a second section 25 which may be a chain or a textile rope which connects the submerged float 24 to a floating object 26, such as a beacon, a fire, or as shown in FIG. 5, a buoy on which may for example moor a pleasure boat 22. This section 25 has a length and diameter sufficient to reach the surface and dampen the traction.

  In known manner, it is desirable that the second section 25 of the wetting line 20 form an angle of between 30 and 60, and more particularly 45, when it is stretched with respect to the X axis of the rod 2 of the anchoring device 1, so as to allow an equal distribution in a horizontal plane and in a vertical plane of the force exerted on said seabed 21.

  The buoy 26 is of variable size, shape and color depending on the use of the mooring line 20. In addition, two cords 27 also of variable length, size and color are attached to the buoy 26 so that stow or moor the vessel 22. Depending on the final use of the anchor line, the number of ropes may vary. Although the invention has been described in connection with several particular embodiments, it is obvious that it is not limited thereto and that it comprises all the technical equivalents of the means described and their combinations if they are within the scope of the invention.

Claims (9)

  Anchoring device (1) for a permanent and / or semi-permanent wetting line, comprising a rod (2) extending along a longitudinal axis X, said rod (2) carrying: at least one helically shaped surface, said helical blade (3), said blade (3) being intended to be screwed into a seabed (21), and having an upper end (3a) and a lower end (3b) extending radially by relative to said rod (2), 10 - a fastening means (4), such as an eye, a ring or a loop, disposed at one end of said rod (2) and intended to protrude from the outside the seabed (21), said attachment means (4) being intended to be connected to said wetting line (20), characterized in that said at least one blade (3) has an evolutionary step in the direction screwing in direction X.   2. anchoring device (1) according to claim 1, characterized in that said blade (3) has a nominal pitch substantially constant except for a first sector (A) extending from the upper edge ( 3a) and having a substantially zero pitch. 20   3. Anchoring device (1) according to claim 1 or 2, characterized in that said blade (3) further has a pitch variation sector (C), having a decrease of said pitch (Cl) relative to the pitch nominal followed by an increase (C2) to return to the nominal pitch, so as to create on the surface of the blade a concave sector.   4. Anchoring device (1) according to claim 2, characterized in that the first sector (A) extends over at least 60.   5. Anchoring device (1) according to claim 3, characterized in that the pitch variation sector (C) extends over substantially 90 and is positioned substantially between the radii at 180 and 270 of the end. upper part of said blade (3a).   6. Anchoring device (1) according to one of the preceding claims, characterized in that the radius of the blade (3) is substantially constant. 14   7. Anchoring device (1) according to claim 6, characterized in that the blade (3) is formed by deformation of a flat metal plate shaped disc slit along one of its spokes.   8. Anchoring device (1) according to one of the preceding claims, characterized in that the pitch of the blade (3) is in the order of magnitude of the radius of said blade (3) and in that the not on the sector of variation of step (C) passes by a minimum of 0 and by a maximum equal to twice the nominal pitch.   9. Anchoring device (1) according to one of the preceding claims, characterized in that it comprises a plurality of helical blades (3) arranged along said rod (2) discontinuously, so as to form a helical spiral discontinuous. 1O.Dispositif anchor (1) according to one of the preceding, characterized in that it comprises an anchor blade, said blade primer, of radius less than or equal to that of the other blades and arranged at the lower part of the rod (2) so as to ensure piercing said seabed, and to facilitate the depression of said anchoring device at the desired level.