ITLT20100004A1 - SUBMERGED BEARING STRUCTURE - Google Patents

Description

DESCRIPTION

TECHNICAL FIELD

The present invention relates to the realization of a submerged bearing structure according to the characteristics set out in the part characterized by claim 1.

STATE OF THE TECHNIQUE

In the field of "OFF-SHORE" marine industrial activities, there is a need to install structures and / or equipment that are not subject to the fluctuations of the sea waves and that are as stable as possible, such as platforms for the extraction of oil , Gas and natural resources in general but also Wind turbines for the production of electricity from wind sources, etc.

In the prior art we proceeded, with the exception of some extraction platforms, to carry out installations of marine systems that did not suffer the fluctuations of the wave motion and that met the technical requirements of functionality, with direct fixing to the seabed and at depths that generally do not exceed 30m. This solution has led to the construction of industrial settlements relatively close to the coasts with a significant environmental impact and a consequent severe limitation also in terms of exploitation of natural resources in relation to the extent of the sea surface available.

One of the highly exploitable natural resources in the sea is wind power. The exploitation of wind energy has had a great development in the world in recent years. This activity has led to the creation of real "wind farms" consisting of a large number of wind turbines arranged along the mountain ridges. Inevitably, suitable sites began to be scarce and, consequently, the size of the machines gradually increased to reach truly impressive dimensions (height of the towers and rotor diameters of the order of 100 meters). This phenomenon has had a significant environmental impact, especially from the landscape point of view.

In recent years, the wind energy production policy has turned its attention to the construction of offshore wind farms, as these present greater efficiency from the point of view of exploiting the wind potential and are generally characterized by environmental and visual impacts. lower than the systems installed on the ground.

The great difficulty in the construction of installations of this type is the simultaneous presence of both optimal climatic conditions and geomorphological conformations of the continental shelf that make the construction and maintenance of these parks attractive from an economic point of view. In this sense, the most appropriate areas where to install this type of systems are shallow seas characterized by easy accessibility for maintenance vehicles and located in areas where the performance of other human activities, such as fishing and navigation, are not disturbed or penalized by the presence of wind turbine towers and all ancillary infrastructures.

One solution is to build offshore wind farms where it would have no impact on the population. Undoubtedly, the installation away from the coasts is an optimal solution both in terms of impact and production but it is necessary to use off-shore structures suitable for this purpose.

The shape of the platform and / or the supporting structure depends on various factors, which are primarily controlled by the violence of the existing actions at sea (tides, surface and depth currents, wind actions, possible seismicity in the area, etc.).

PURPOSE OF THE INVENTION

The object of the present invention is to solve the previously reported problems by providing a submerged bearing structure which acts as a foundation and / or secure and stable fixing of structures and / or equipment.

CONCEPT OF THE INVENTION

The object is achieved with the characteristics of claim 1. The subsequent claims represent advantageous solutions.

ADVANTAGES OF THE INVENTION

The solution proposed according to the present invention has both advantages from the environmental point of view, due to the lower impact of the materials, and from the point of view of safety, due to its mechanical and fluid-dynamic characteristics, and in detail:

• allow the installation of structures, such as wind turbines, etc., in deep waters greater than 30m. The installation can take place with the "submerged supporting structure" in a state of emergence, allowing you to work above the surface of the water and then proceed with setting it up at the designated depth by means of the rooms and / or lockers (G);

• the controlled water filling and emptying of the rooms and / or watertight lockers (G figures 3/11 and 8/11), guarantee the structure to be supported an adjustment of its vertical axis with respect to the horizontal plane, the adjustment of the thrust of sustenance and / or emergence, as well as the displacement of the center of gravity (M);

• the spherical shape of the part (S figures 3/11 and 8/11) guarantees the maximum solution to the turbulent fluid dynamics effects deriving from any direction, the maximum thrust of emergence in terms of volume and the maximum structural strength, as well as the cylindrical parts ( (T3 or T1) and T figure 3/11 and 8/11);

• The parts T3 or T1 are the extension of the part (T), forming with the latter, a single cylindrical body on which the spherical part (S), by means of suitable mechanical jacks, can slide by modifying the height of the point of center of gravity (M). In moving, the length of the detail (T) is also modified which, with the detail (P), generates an increase or a decrease in the pendulum effect (illustrated later).

• the multiple independent watertight chambers (G) (figures 3/11 and 8/11) make it practically unsinkable;

• In case of breakage of the fixing and / or anchoring cables from the seabed ((C or C1) and D figure 3/11 and 4/11 or (B or B1) and D figure 8/11 and 9/11), it loses stabilization control along the vertical and horizontal axes, losing the depth set-up and causing the supporting structure to emerge. At this point, the suitably sized counterweight of the ballast (detail P figures 3/11 and 8/11) generates a pendulum effect tending, with each fluctuation of the wave and / or wind motion, to bring the angle between the axis vertical of the emerged overlying structure and that of the gravitational direction passing through the center of gravity point of the load-bearing structure object of the present invention, at 0 °, preventing overturning of the overlying structure. In fact, in the case of the wind turbine, it will remain in a vertical position;

• The fixing detail (C, L, C1, figure 2 / 11,3 / 11 and 5/11), guarantees the oscillatory stabilization of the vertical axis with respect to the horizontal plane. If the vertical axis of the emerged structure must be perpendicular to the horizontal plane, their angle will be kept at 90 °. It guarantees the depth setting, as well as prevents the rotational effect around the vertical axis;

• the fixing detail (B, L, B1 figure 7 / 11,8 / 11 and 10/11), in the case of multiple installations, guarantees the oscillatory stabilization of the vertical axis with respect to the horizontal plane. If the vertical axis of the emerged structure must be perpendicular to the horizontal plane, their angle will be kept at 90 °. It also prevents the rotational effect around the vertical axis; • The fastening detail (D figures 4/11 and 9/11) guarantees maximum stabilization on the depth structure and contributes to stabilization with respect to the horizontal plane;

• the submerged structure guarantees non-exposure to wave motion and protection against erosion of materials due to salt and oxygen.

LIST OF FIGURES WITH BRIEF DESCRIPTION

The invention will now be described in more detail with the aid of the following drawings:

Figure 1/11 is a schematic representation of the first type of submerged bearing structure, concerning the present invention, with a wind turbine for demonstration purposes;

Figure 2/11 is a schematic representation of several submerged load-bearing structures highlighting the first type of load-bearing structure with the first fastening and / or anchoring system concerning the present invention, with wind turbines for demonstration purposes;

• figure 3/11 is a detail view of figures 1/11 and 2/11;

Figure 4/11 is a detail view of figures 1/11 and 2/11;

Figure 5/11 is a detail view of figure 2/11;

• figure 6/11 is a schematic representation of the second type of submerged bearing structure concerning the present invention and for multiple installations, with a wind turbine for demonstration purposes;

Figure 7/11 is a schematic representation of several submerged load-bearing structures, highlighting the second type of load-bearing structure with the second fixing and / or anchoring system concerning the present invention, with wind generators for demonstration purposes;

Figure 8/11 is a detail view of figure 7/11;

Figure 9/11 is a detail view of figures 6/11 and 7/11;

Figure 10/11 is a detail view of figure 7/11;

• Figure 11/11 is a schematic representation seen from above, of a group of submerged load-bearing structures relating to the present invention, connected to each other by means of fastening and / or anchoring systems.

DETAILED DESCRIPTION OF THE INVENTION

The following description illustrates in detail the submerged load-bearing structures with the different fastening and / or anchoring systems.

- Figures 1 / 11,2 / 11,3 / 11,4 / 11 and 5/11 show the first type of submerged supporting structure with the first fixing and / or anchoring system (C, L, C1 and D), object of the present invention. The body of the submerged load-bearing structure consists of a spherical (S), a cylindrical part (T, T3) and a spherical ballast (P).

• The cylindrical structure (T3), is the coupling part of the future structure to be supported and is the extension of the detail (T), forming with the latter, a single cylindrical body on which the spherical part (S), by means of suitable mechanical jacks, it can slide by changing the height of the center of gravity point (M). In moving, the length of the detail (T) is also modified which, with the detail (P), generates an increase or a decrease in the pendulum effect (illustrated later).

• The spherical structure (S), contains within it, multiple rooms and / or watertight lockers (G), suitable to allow, by means of their single flooding or emptying, the modification of the center of gravity (M) according to the needs structure of the emerged structure to be supported and at the same time guaranteeing, in case of breakage and / or perforation of one room and / or locker, the non-flooding of the others (principle of unsinkability). The diameter varies according to the emerged structure to be supported.

The cylindrical structure (T, T3), is enslaved, in addition to the attachment of the structure to be supported and the sliding of the spherical structure (S), to the connection and / or support of the spherical ballast (P).

It contains inside, multiple rooms and / or watertight lockers (G), designed to allow, by means of their single flooding or emptying, the modification of the center of gravity (M) according to the needs of the structure emerged to be supported. and at the same time ensuring, in the event of breakage and / or perforation of one room and / or locker, the non-flooding of the others (principle of unsinkability). Its length varies according to the force (pendulum effect), in relation to the weight of the spherical ballast (P), necessary to guarantee the original upright position of the emerged supported structure (A), preventing it from overturning in case of breakage of the fasteners and / or anchors (C, C1, D or B, B1, D).

The spherical ballast (P), is enslaved, by means of its appropriately sized mass, to guarantee the original upright position of the emerged supported structure (A), preventing it from overturning in case of breakage of the fasteners and / or anchors (C, C1, D or B, B1, D). The diameter varies according to the emerged structure to be supported.

The first fixing and / or anchoring system is composed of cables (C, C1) which connect the sphere (S), by means of the detail (L fig. 5/11), to the attachment points (F) on the backdrop (H ) and by cables (D) that connect the spherical ballast (P) to the attachment points (F) on the bottom (H).

The cables (C, C1), in addition to ensuring an anchoring point to the seabed, serve to ensure the oscillatory stabilization of the vertical axis with respect to the horizontal plane. If the vertical axis of the emerged structure must be perpendicular to the horizontal plane, their angle will be kept at 90 °. In addition, they guarantee the depth setting, as well as prevent the rotational effect around the vertical axis.

The detail (L) is enslaved for greater safety, as well as to avoid breakage of the cables due to abrasion. It is used for multiple installations (fig. 5/11).

The cables (D), in addition to ensuring an anchoring point (F) to the seabed (H), serve to ensure maximum stabilization on the depth set-up and contribute to the oscillatory stabilization of the vertical axis with respect to the horizontal plane.

- Figures 6 / 11,7 / 11,811,9 / 11 and 10/11 show the second type of submerged supporting structure with the second fixing and / or anchoring system (B, L, B1 and D), object of the present invention . The body of the submerged load-bearing structure is made up of a spherical (S), a cylindrical structure (T, T1) and a spherical ballast (detail P).

• The cylindrical structure (T1) has the same technical characteristics as the detail (T3) mentioned above, with the only difference in the connection points of the cables (B).

• The spherical structure (S) has the same technical characteristics of the first type mentioned above.

• The cylindrical structure (T, T1), has the same technical characteristics of the detail (T, T3) mentioned above, with the only difference in the connection points of the cables (B1).

• The spherical ballast (P) has the same technical characteristics as the first type mentioned above.

• The second fixing and / or anchoring system can only be used in the case of installations of multiple submerged load-bearing structures. The system is composed of cables (B, B1) which connect the cylindrical part (T1) of the first submerged supporting structure, by means of the detail (L fig. 10/11), to the cylindrical structure (T) of the second submerged supporting structure and from the cables (D) that connect the ballast (P) to the attachment points (F) on the bottom (H).

The cables (B, B1), serve to ensure the oscillatory stabilization of the vertical axis with respect to the horizontal plane. If the vertical axis of the emerged structure must be perpendicular to the horizontal plane, their angle will be kept at 90 °. In addition, they guarantee the depth setting, as well as prevent the rotational effect around the vertical axis.

The detail (L) is enslaved for greater safety, as well as to avoid breakage of the cables due to abrasion. It is used for multiple installations (fig.10 / 11).

The cables (D), in addition to ensuring an anchoring point (F) to the seabed (H), serve to ensure stabilization on the depth set-up and contribute to the oscillatory stabilization of the vertical axis with respect to the horizontal plane.

Figure 11/11 is a schematic representation seen from above, of a group of submerged bearing structures of the first and second types, concerning the present invention, connected together by means of the fixing and / or anchoring systems ((C, F or C, L, C1, F or T1, B, L, B1, T) and D, F of figures 1 / 11.2 / 11.3 / 11.4 / 11.5 / 11.6 / 11.7 / 11,811,9 / 11 and 10/11).

The description of the present invention has been made with reference to an embodiment and functionality thereof and that the invention is not limited by the previous description, but includes all those alterations, modifications and variations in accordance with the attached claims. It is understood that the term "cable" and / or "cables" as used throughout the description is to be understood in its broadest sense, and may also include other flexible links such as chains, hawsers, etc.

It is specified that the wind turbine shown on the invention is only indicative and enslaved to show a type of use of the present invention which can be used for the maintenance of multiple structures and / or equipment.

Claims (20)

CLAIMS 1. Submerged load-bearing structure capable of supporting a structure and / or equipment regardless of its mass, having the attitude control of the vertical axis with respect to the horizontal plane, the attitude control on the depth, the non-rotation around the vertical axis , a very high resistance to turbulent fluid dynamics phenomena, a high unsinkability coefficient and non-tipping. 2. Submerged load-bearing structure according to claim 1., characterized by a cylindrical part (T3), a single body with the cylindrical part (T), containing floodproof / emptied chambers and / or lockers (G) located, according to a side view, on the various horizontal levels. Served for fixing the structure and / or equipment to be supported. Its thickness, length and the number of rooms and / or lockers vary according to the mass of the structure to be supported. 3. Submerged load-bearing structure according to claim 1, characterized by a spherical part (S), capable of sliding along the vertical axis of the cylindrical part (T), having connections for hooking the cables (C) and having, in the inside, rooms and / or watertight lockers (G) that can be flooded / emptied located, according to a side view, on the various horizontal levels and divided, according to a view from above, into segments for each level. Its diameter and the number of rooms and / or lockers depend on the mass of the structure to be supported. 4. Submerged load-bearing structure according to claim 1, characterized by a cylindrical part (T), containing watertight / emptied chambers and / or lockers (G) located, according to a side view, on the various horizontal levels. Its thickness, length and the number of rooms and / or lockers vary according to the mass of the structure to be supported. 5. Submerged supporting structure according to claim 1., characterized by a spherical ballast (P), having connections for attaching cables (D). Its diameter varies according to the mass of the structure to be supported. 6. Submerged load-bearing structure according to claim 1, characterized by a fastening and / or anchoring system ((C, F or C, L, C1, F) and D, F) comprising one or more cables ((C or C , C1) and D), the particular fixing (L) and a fixing and / or anchoring point (F) to the bottom (H). 7. Submerged load-bearing structure according to claim 6., characterized by the cable (s) (C) which are hooked, on one end to the spherical part (S) and on the other end to the fixing and / or anchoring point (F) to the seabed (H). Their length and thickness varies according to the force loads to be supported. 8. Submerged supporting structure according to claim 6., characterized by one or more cables (C) which are hooked, from one end to the spherical part (S) and from the other end to the particular fixing point (L). Their length and thickness varies according to the force loads to be supported. 9. Submerged load-bearing structure according to claim 6., characterized by one or more cables (C1) which are hooked, on one end to the particular fixing point (L) and on the other end to the fixing and / or anchoring point ( F) to the seabed (H). Their length and thickness varies according to the force loads to be supported. 10. Submerged load-bearing structure according to claim 6., characterized by one or more cables (D) which are hooked, at one end to the spherical ballast (P) and at the other end to the fixing and / or anchoring point (F) to the seabed (H). Their length and thickness varies according to the force loads to be supported. 11. Submerged load-bearing structure according to claim 1., characterized by a cylindrical part (T1), a single body with a cylindrical part (T), having connections for hooking cables (B), containing watertight chambers and / or lockers (G) floodable / emptied located, according to a side view, on the various horizontal levels. Its thickness, length and the number of rooms and / or lockers vary according to the mass of the structure to be supported. 12. Submerged load-bearing structure according to claim 1, characterized by a spherical part (S), capable of sliding along the vertical axis of the cylindrical part (T), having inside it watertight chambers and / or lockers (G) that can be flooded / emptied units located, according to a side view, on the various horizontal levels divided, according to a view from above, into segments for each level. Its diameter and the number of rooms and / or lockers vary according to the mass of the structure to be supported. 13. Submerged load-bearing structure according to claim 1, characterized by a cylindrical part (T), having connections for hooking the cables (B1) and containing rooms and / or watertight lockers (G) that can be flooded / emptied displaced, according to a view lateral, on the various horizontal levels. Its thickness, length and the number of rooms and / or lockers vary according to the mass of the structure to be supported. 14. Submerged load-bearing structure according to claim 1, characterized by a fixing and / or anchoring system (B, L, B1) comprising one or more cables (B, B1 and D), the particular fixing (L) and a point fixing and / or anchoring (F) to the bottom (H). 15. Submerged supporting structure according to claim 14., characterized by one or more cables (B) which are hooked, on one end to the cylindrical part (T1) and on the other end to the particular fixing (L). Their length and thickness varies according to the force loads to be supported. 16. Submerged supporting structure according to claim 14., characterized by one or more cables (B1) which are hooked, from one end to the particular fixing (L) and from the other end to the cylindrical part (T). Their length and thickness varies according to the force loads to be supported. 17. Submerged bearing structure according to claims 6 and 14, characterized by the particular fixing point (L) having the function of hooking the cables (C, C1 or B, B1). Its size and thickness varies according to the force loads to be supported. 18. Submerged load-bearing structure according to any preceding claim, characterized by the materials which can be steel, steel, cement, concrete, reinforced concrete fibers, composite materials, or any other suitable material. 19. Submerged load-bearing structure according to any preceding claim, characterized by the fixing and / or anchoring point (F), equivalent to the above ground and / or bottom attachment point of a fixing structure located below the seabed level. 20. Submerged load-bearing structure according to each preceding claim, characterized by the multiple installation system in accordance with fig.11 / 11.