EP3303115A1

EP3303115A1 - Devices and methods for producing a large-size floating structure

Info

Publication number: EP3303115A1
Application number: EP16725114.9A
Authority: EP
Inventors: Richard Dziewolski
Original assignee: Individual
Current assignee: Individual
Priority date: 2015-06-05
Filing date: 2016-05-24
Publication date: 2018-04-11
Also published as: FR3037089A1; FR3037089B1; WO2016193064A1; US20180170489A1

Abstract

The present invention relates to a large-size floating structure which meets the needs for extending the activities of coastal towns. The architectural and technical design resulting from the present invention can accommodate several thousand inhabitants, while attracting many visitors and customers to live, work and enjoy varied leisure facilities. This energy-autonomous marine district, which is non-polluting and environmentally friendly, constitutes an example of sustainable development. Each component of the structure of the barge provides a maximum of functions: structural, functional, ecological and architectural. By concentrating all of the activities of a town in a single complex, it is easier and more economical to resolve all the problems of sustainable development and safety than in the habitat next to the coast.

Description

DEVICES AND METHODS OF MANUFACTURING FOR FLOATING STRUCTURE

LARGE DIMENSIONS

Field of the invention

The invention relates to the field of large floating structures. More specifically, the invention relates to a floating artificial island that is autonomous in energy and environmentally friendly.

State of the art The creation of floating artificial islands in the form of barges or offshore platforms for tourist purposes, requires solving many different problems including:

- the choice of shapes and layouts sought by customers, based on market studies guaranteeing a high filling rate;

- carrying out studies to solve all the technical problems and to justify the feasibility of the concept;

- the anchoring study of the barge, which determines the technical feasibility;

- The construction of the large float, difficult to achieve in existing shipyards.

Thus, the floating barge must adapt to different types of locations and anchoring, such as:

- an autonomous island located off the coast and accessible by boat and helicopter (barge anchored by cables and chains for great depths or resting on piles - jacket);

- in islands connected to the shore by a tunnel and / or a bridge (platform on piles).

Each type of anchorage of the floating barge must be studied taking into account the zone of implantation, notably the distance from the shore, the depth of the sea, the wind, the current, the swell, the tides, and the rising waters. In addition, the floating structure must withstand extreme conditions. Also, to ensure a service life greater than 100 years, the float structure must have good corrosion resistance and a very good seal.

In addition, an artificial island forming a marine city for several thousand inhabitants, tourists, visitors and staff, must have easy access (pedestrians, cars, boats, helicopter requiring a port for ferry and pleasure boats and a helipad) .

Safety is a major point and the structure must have a fire resistance in accordance with standards, and allow a rapid evacuation (boats - rescue ferry) in case of accident or fire.

There must also be a compliance of facilities with the standards of sustainable development and energy saving. Production and autonomy of energy must be able to be obtained by wind turbines, solar thermal and photovoltaic panels, generators, and / or non-polluting fuel (CO2 ± = 0).

Such islands must be built with respect for the environment, with the filtration of wastewater, the production and storage of drinking water, the treatment of waste.

Also, the realization of the structures intended to support the photovoltaic panels, thermal, and the windows which must be integrated in the monumental architecture of the marine cities receiving the public, must be the subject of particular studies, among which the others. optimization of weight and cost.

Finally, access to the sea must be done safely for the inhabitants (floating pools, pleasure boats). The patent application FR28780865 of CCERET Engineering by the same inventor Richard Dziewolski as the present application, describes a barge intended to form a floating artificial island, serving, in a preferred application, a fully integrated tourism-oriented real estate complex, located on a marine site or assimilated (lake, swamp, etc.). However, this barge does not fully meet the requirements described above. And improvements are proposed in this application. Summary of the invention

The solution described aims to make improvements to the device presented in the prior art to reduce the overall cost of manufacture.

To achieve this objective, the present invention provides various devices and methods for increasing the resistance of the barge, facilitate the construction of the float, allow access to the sea to residents and tourists, facilitate the compliance of facilities with the standards of sustainable development and energy saving and propose an alternative anchoring of the barge.

Thus the proposed improvements concern: - the replacement of braces by a three-dimensional structure in the form of a dome supporting solar panels, allowing the reduction of the weight of the steel and simplifying the assembly;

- a structure supporting the atrium canopy (ref 1 1 figure 3) more resistant supporting a canopy and a belvedere; - a new process for the construction of a large float in a steel-concrete composite structure;

- protection of the barge against the impact of boats and other objects, beaches, pontoons, floating pools providing several functions;

- An anchoring device for the cable barge completed by a new variant. Thus, a first object (A1) of the invention is a three-dimensional structure with a dotted-shaped multidirectional lattice web for the current portion. This structure in a preferred implementation, is supported by 6 crutches fixed on the arms of the barge and 48 inclined posts fixed on the lower structure, the whole constituting a rigid assembly allowing:

- Increase the strength of the barge and remove the bracing provided in the aforementioned patent;

- to withstand the forces of extreme wind (250 to 300 km / h); - to support the vertical and horizontal reactions of the belvedere;

- to support the photovoltaic panels for the production of electricity, and thermal for the heating of the water;

- to act as a sunshade for the canopy below lighting the atrium; - to evacuate persons occupying the belvedere by means of the emergency stairs located above;

- act as an umbrella to collect rainwater for future use; and

- to simplify the assembly and limit the cost.

A second object (A2) of the present invention is a three-dimensional structure with a web having a geometry allowing good resistance to buckling of the walls and allowing:

- to support the canopy of a central atrium;

- to support the vertical and horizontal reactions of a panoramic gazebo restaurant, located at the top of the barge;

- To ensure the transverse stability of the central mast, the latter playing the role, during the assembly phase, installation of the crane and in the operating phase to support the weight of a lookout, panoramic lifts, emergency stairs and the passage of fluids and cables; and

- to simplify the assembly and limit the cost.

A third object (A3) of the invention relates to a method of constructing a large float, greater than 100 m, which is difficult to achieve in the current shipyards. The process is innovative in that the float is decomposed into several elements made of a mixed concrete steel structure, prefabricated at the factory and assembled in a buoyant site in a construction site, of low draft, but while ensuring a good seal, a excellent resistance to corrosion, and allowing the reduction of the weight of steel compared to large ships made of steel. The assembly of these three-dimensional structures of great span, double curvature, composed of small elements (nodes + bars) which are assembled on site, is particularly complex given the number of different elements of the structure and cover having variable dimensions to assemble and to ensure tightness. A fourth object (A4) of the present invention relates to pontoon beaches, forming pools and attached to dikes all around the barge. These pontoons are fixed by means of articulated joints ensuring the adjustment of draft. These pontoon beaches are interconnected at the bottom by nets arranged horizontally and, on the sea side, by cables and nets arranged vertically. The whole forms bathing areas, and provides several functions:

- protection against shocks from boats and other floating objects;

- be breakwaters reducing the nuisance of the waves;

- protection of bathing areas, drowning, sharks, jellyfish and oil pollution.

A fifth object (A5) of the invention relates to a variant of anchoring by a battery or jacket device. This anchoring is intended to reduce the movements of the barge in the case of connection with the coastline tunnel and bridge. The batteries support horizontal and vertical loads resulting from additional operating overloads and climatic loads. The structure that is the subject of the present invention can be adapted to the different types of anchorages studied as a function of tides and rising waters, resulting from a global warming. It can also be sized to withstand tsunami efforts. In the latter case the depth of the sea must be greater than 60 m and the efforts must be defined by basin tests. FIG. 8 represents compartments provided in the float for accommodating various connecting devices adapted to the type of anchoring of the barge (with or without draft adjustment).

Thus, the invention relates to a three-dimensional structure comprising a dovetail-shaped multidirectional lattice web, the dome being supported by a plurality of crutches, the structure further comprising a plurality of inclined posts fixed to the lower part of the structure, the structure being characterized in that is composed of prefabricated slabs, each prefabricated slice comprising two curved chords, sleepers, and diagonals.

Advantageously, each crutch is a prefabricated slice whose drawings are formed by rotating an arc rotating about a vertical axis of a modular angle equal to 360 / n.

In one embodiment, the cross members are square or rectangular tubes, and the diagonals are round tubes.

Advantageously, the curved chords are obtained by rotation about a vertical axis of an arc placed upside down obtained by hot bending of the square tubes.

In an implementation variant, the structure comprises a network of water gutters for rainwater recovery.

The invention also relates to a barge comprising the three-dimensional structure as described. In an implementation of the barge, the three-dimensional structure comprises six crutches fixed on the arms of the barge and forty eight inclined poles, all constituting a rigid assembly for increasing the resistance of the barge.

In one embodiment, the multidirectional trellis sheet has a geometry to support a double-glazed atrium canopy, this sheet may be included in a barge. The invention also relates to a large barge having a dome in the upper part providing bracing and supporting photovoltaic and thermal panels for the production of electricity and for heating. The dome forming a composite assembly consists of a sliced precast three-dimensional tubular structure according to the claimed method, a bent steel sheet welded to the cross members and chords of the structure, L-shaped stiffeners welded spotwise to the sheet metal of steel, an armature of geometry predefined by calculations, lightweight concrete with the addition of a product making the waterproof concrete filling the sheet, the stiffeners and the frame. It also includes a network of tubes allowing the circulation of a liquid to firstly cool the photovoltaic panels and the metal structure thus reducing the thermal expansion of the steel and on the other hand to heat the water. The cupola has air spaces and panels composed of safety glazing and glued photovoltaic cells for the production of electricity.

The barge may include means to form a tourist barge or a floating artificial island. These means include at least:

- A large habitable float steel-concrete composite structure, said float comprising prefabricated elements assembled by construction joints;

- beaches, pontoons; and

- An anchoring system of the barge in jackets-piles to reduce the movement of the barge.

Thus, the invention also relates to a barge comprising a large float in a mixed-steel-concrete structure, the float being composed of prefabricated elements which are assembled in flotation, and where each element in direct contact with the seawater has a good seal, good corrosion resistance and a service life of 100 years in that the walls in direct contact with seawater consist of steel sheet, stiffeners welded to the sheet and honeycomb sleepers welded on the sheet, thus forming a formwork in interior ensuring the perfect sealing of the float. The float is also composed of a longitudinal and transverse reinforcement, in concrete with the addition of a product rendering the concrete waterproof. The external formwork in direct contact with seawater can be either in a coating imitating rocks such as in aquariums or ports, with elements on the outer walls of polished concrete with the addition of a component at the base of resin avoiding the bursting of the concrete, as the whole participates in the overall resistance and ensures the sealing of the walls and the protection against corrosion.

In one possible embodiment, the invention is a tourist barge comprising a peripheral protection consisting of pontoon beaches. The pontoon beaches form pools, fixed on dikes all around the barge and connected at the bottom by nets arranged horizontally and on the sea side by cables and nets arranged vertically, as the whole forms swimming areas . These areas perform several functions:

- protect against shocks from boats and other floating objects;

- be a breakwater reducing the nuisance of the waves;

- provide supervised bathing areas against drowning, shark attacks, jellyfish and oil pollution.

Advantageously, the pontoon beaches consist of:

- console beaches embedded in the dike;

- pontoons made of waterproof reinforced concrete caissons (or other materials) with ballast compartments for draft adjustment;

- Removable stainless steel joints ensuring the articulation of the pontoons on the brackets and allowing the draft adjustment;

- Reinforced concrete stairs fixed on the brackets supporting the net;

- a pool bottom made of net supporting the weight of swimmers and protecting them from drowning, sharks and jellyfish;

- a device for protecting swimming pools against shocks from boats and various floating objects, consisting of an upper cable supported by float buoys, a lower cable suspended on an upper cable and supporting the net and where the net is placed vertically and fixed on the cables protecting the pool against sharks, jellyfish and oil pollution.

The invention also relates to a barge which has an anchoring device reducing the barge movements under the effect of external loads and which is essential in the case of a connection of the barge with the banks using tunnels and walkways. The anchoring device is characterized in that the fixing of the barge is either on piles of tubes drilled and embedded in the ground and filled with reinforced concrete, or on jackets with the aid of a device allowing horizontal adjustment and vertical and allowing the assembly and disassembly of the barge, and allowing a modification of the draft of the barge depending on the rising waters.

Advantageously, the float of the barge comprises 16 compartments intended for the anchorage, four compartments located under six arms taking the efforts that are concentrated at the ends of the dikes.

Advantageously each compartment has a structure for assembling the connecting tubes to be fixed inside the battery tubes providing the connection between the barge and the stacks implanted under the bottom level of the barge.

Advantageously, a suitable mounting device allows up and down sleeve tubes and move horizontally to adjust with the implantation of the batteries.

Advantageously different types of connections with jacket batteries can be provided and chosen according to local conditions of implementation of the platform, as follows:

- perfect fitting of non-removable batteries in the structure of the barge: either by welding the sleeves with the batteries; either by filling the connecting tubes with concrete with additional reinforcement ensuring the anchoring; either by both;

- Installation of the batteries in the barge, removable and adjustable, using the device (J) detailed in Figures 17 and 18;

- Installation of the connecting tube in the batteries by welding and concreting and articulation with vertical sliding of the tube ensuring the connection with a fitting tube embedded by welding and concreting in the anchoring room. This interlocking tube can be coated internally with Teflon® facilitating vertical sliding (solution to be adopted in the case of large tides taking only the horizontal forces).

The invention also relates to a method of constructing large floats in a steel-concrete composite structure, comprising the steps of:

to produce in a factory prefabricated elements for the float, each element being decomposed into several prefabricated sections, the dimensions are chosen according to the type of transport used between the plant and an assembly yard, and where each element coming into direct contact with the seawater consists of a mixed steel-concrete structure; and

- assemble the prefabricated elements by construction joints.

Description of figures

Various aspects and advantages of the invention will appear in support of the description of a preferred embodiment of the invention, but without limitation, with reference to the figures below: FIG. 1 illustrates the structure of the present invention including improvement devices;

Figure 2 shows the perspective diagram of the dome of Figure 1;

Figure 3 illustrates the principle of prefabrication in beams of the structure of Figure 1; FIG. 4 illustrates the principle of gusset assembly of the slices of FIG. 3;

Figure 5 shows a perspective diagram of the structure supporting the canopy of the atrium;

Figure 6 shows the principle of prefabrication of the structure supporting the canopy of the atrium; Figure 7 shows the assembly details of the structure of Figure 1;

Figures 8a and 8b illustrate the double bottom of the float of the barge decomposed into prefabricated elements;

Figures 9, 10 and 1 1 illustrate the principle of assembly of the prefabricated elements shown in Figures 8a and 8b; Figures 12 to 15 illustrate in different views, sections and perspectives the ranges- pontoons of the present invention;

Figures 16, 17 and 18 show the principle of connection of the barge with the jackets.

Detailed description of the invention

The present invention proposes to improve the structure described in the prior art.

Thus, the description of the elements common to the known device is not repeated, and only the improvement elements are described in more detail.

Thus, the improvements with respect to the object of the aforementioned French patent reside mainly in 5 axes.

It should however be noted that these devices may have applications in other areas of construction than that of floating structures.

A first axis of improvement (A1) lies in the dome-shaped structure participating in the resistance of the barge and supporting a cover. The cover consists of: stiffened metal sheet, light reinforced concrete, sealing elements, tubing networks allowing the circulation of water to cool the metal structure undergoing significant expansions and to heat the water (heat pump). heat), and photovoltaic or thermal panels located outside.

A second axis of improvement (A2) lies in the three-dimensional structure to a sheet, obtained according to a same method of construction and assembly as the dome-shaped structure but having a different geometry and supporting a canopy of the double atrium. glazing or other type of cover.

A third improvement axis (A3) relates to a method of constructing large floats in a steel-concrete composite structure. This process is innovative in that the float is decomposed into prefabricated elements and reassembled, while allowing each element in direct contact with seawater to ensure good sealing, good resistance to corrosion. Advantageously, by this method, the construction of the structure brings a strong economy in the use of steel.

A fourth axis of improvement (A4) concerns beaches - pontoons, forming swimming pools, fixed on dykes all around the barge, and connected at the bottom by nets arranged horizontally and, on the sea side by cables and nets arranged vertically, as the whole forms bathing areas ensuring several functions: - protection against shocks from boats and other floating objects;

- a breakwater reducing the nuisance of the waves;

- protection of bathing areas against drowning, sharks, jellyfish and oil pollution.

A fifth improvement axis A5 relates to the anchoring device of the barge to reduce the movement of the barge and provide greater security than the known cable anchor device. This device is essential in the case of links of the island with the littoral by the tunnel and the footbridge. The anchoring device uses batteries or jackets that support the forces of the swell, the current and the wind. This device is advantageously adapted to weather conditions in the Mediterranean where the depth is greater than 30 m, the tides do not exceed 50 cm, the rise in water estimated at ± 1.5 m, the extreme swell is 6 m and the extreme wind 300 km / h. This device makes it possible to reduce the movements of the barge which is essential in the case of links of the island with the littoral by tunnel and footbridge.

Reference is made to Figure 1 which shows the structure of the present invention including enhancement devices. Are represented by references in parentheses:

(1) the dome

(2) the structure of the atrium

(3) the float (4) the pontoon beaches

(5) fire escape stairs

(6) the gutters and downspout inside the steel tubes supporting the structure to evacuate the rainwater (7) crutches ensuring the transmission of cupola forces

(8) piles allowing anchoring of the platform, ensuring the transmission of horizontal and vertical forces

(9) gazebo, panoramic restaurant. Figure 2 shows the perspective diagram of the three-dimensional structure with a dotted-shaped multidirectional lattice web for the current portion. This structure is supported by 6 crutches (27) fixed on the arms of the barge and 48 inclined posts (28) fixed on the lower structure constituting with the barge a rigid assembly providing the functions previously described with reference to the object A1.

Water gutters (26) for recovery of rainwater (for storage, filtration and future use) are provided in the lower part of the dome - Fig.1 (6) - Fig.2. (26) - Fig.3 (36) - and the water drops inside the tube poles (28) and posts of 6 crutches (27). The structure is prefabricated by "slices", the lines of which are constituted by rotation of an arc rotating about a vertical axis of a modular angle = 360 / n).

FIG. 3 represents the principle of the modelization of the sketches of the structure where R1 is the radius of curvature of the arc, R2 is the radius of the lower part of the dome, R3 is the radius of the upper part supporting the belvedere ( 34). Each slice consists of 2 curved chords - Fig.3 (31) Fig.4 (43) - crosspieces - Fig.3 (32) and Fig.4 (42) - square or rectangular tubes and diagonals and round tubes - Fig.3 (33) and Fig.4 (43). The curved truss beams forming the "slices" shown in FIGS. 3 and 4 are assembled on site by either welding or bolting using the gussets (45) of FIG. 4 comprising the welded adjusting shims (46). .

The structure of the dome supports photovoltaic and thermal panels in the form of sandwich panels (44) composed of:

- bent stainless steel sheet (T) welded to the cross members and chords of the main structure; - L-shaped stiffeners (C) welded spot on the sheet;

- armature (A) defined by calculation;

- light concrete (D) with the addition of a product making the concrete waterproof;

- insulation + sealing (if needed);

- networks of tubes allowing the circulation of water (idem with heated floors) to, on the one hand, cool the photovoltaic panels and the metal structure and, on the other hand, heat the water (hot water, heating , heat pump);

- vacuum of air;

- Photovoltaic or thermal panels and small wind turbines. Advantageously, this device allows:

- to seal the roof;

thermally isolating the metal structure supporting significant temperature differences;

- to reduce the noise resulting from fixed wind turbines above;

- to produce electricity;

- Heat the water and cool the photovoltaic panels and the metal structure which is heated by the sun and the photovoltaic and thermal panels (reduction of the thermal expansion of the metal structure);

- to simplify and reduce the price of mounting the dome.

Advantageously, the dome designed according to the method of the invention can be used as a cover for buildings of different types: sports buildings, stadiums, hotels, factories, etc. For large spans, the structure of the cupola may include a lower sheet increasing resistance and reducing deformation of the latter.

Figure 5 shows a perspective diagram and the assembly details of the structure supporting the canopy of the atrium (double glazing (74) of Figure 7) and the gazebo (9) fig.1 and (51) fig. 5). This structure is made and assembled as the structure shown in Figure 4 described above. Figure 6 shows the principle prefabrication of the structure supporting the canopy of the atrium. It is decomposed by prefabricated elements and assembled on the site according to the details of Figure 7. The geometry of the structural sketches is obtained by the rotation around a vertical axis (modular angle = 360 / n) of an arc set upside down (bending radius = R1, radius of the atrium = R2, radius of the upper opening = R3 according to the detail of Figure 6).

The elementary slices forming the structure consist of: ribs (61) fig. 6 and (71) fig.7, in square or rectangular tubes, sleepers (62) fig. 6 and (72) fig.7, and diagonals (63) fig. 6 and (73) fig.7, in square, rectangular or round tubes. These wafers welded flat (detail B of Figure 6) are bent hot at the factory. The diagonals and crosspieces are welded to the bent chords (slanted cross sections and diagonals with angles = 360 / 2n). The elements in the form of slices are decomposed in sections (I) fig. 6 whose length depends on the means of transport factory / site. Figure 7 shows the assembly details of two slices of the structure

(plan view and sectional view), comprising:

- chords (71) in square or rectangular tubes

- sleepers (72) and diagonals (73) in square, rectangular or round tubes

- a transverse assembly of the slices of the structure by welding or bolts using the gussets (75)

- A double glazing (74) comprising an aluminum frame, fixed on the cross members (72) and the curved chords (71).

Advantageously, the canopy can be replaced by a cladding or cover for other applications, such as for aero-refrigerant nuclear power plants for example.

Figure 8 illustrates the double bottom of the barge float decomposed in prefabricated elements shown on part (A) and assembled in a cooperating steel formwork shown on part (B). The dimensions of the prefabricated elements (81 to 88) are defined according to the possibilities of the construction sites carrying out these elements.

The metal structure of each element can be broken down into several sections made in several factories. The building site carrying out the elements is in charge of the assembly of the metal sections by welding, the installation of the reinforcements and the concreting of the raft, the sails and the bridge 2 constituting the double-bottom which is then launched and towed in the site of float assembly (a construction yard with sufficient draft).

In FIG. 8, the different elements of the structure referenced 81 to

88: - 1 central element (81) of the central float

- 6 elements (82) of the central float

- 6 elements (83) of the central float

- 6 elements of the arm float (84)

- 3 elements of dikes (85)

- 3 elements of dikes (86)

- 2 SPA items (87)

- 4 bottom elements of the port (88).

The four compartments of the floats (84) indicate the anchoring zones of the barge, either by means of chains and cables, or by means of connections with battery-jackets. This device is described in detail in improvement (A5).

The prefabricated elements defined above are assembled by construction joints shown in FIG. 8 and FIG. 9 by the references (89, 99). Each element in direct contact with the seawater (the plating and the intermediate walls delimiting the prefabricated and towed elements) is made according to the plane of principle of Figures 9, 10 and 1 1. Each element consists of:

- (101) Steel sheet;

- (102) Welded stiffeners on the sheet;

- (103) Alveolar sleepers welded to the sheet, the latter 3 constituting the collaborative formwork ensuring perfect sealing of the float;

- (104) Longitudinal and transverse reinforcement;

- (105) Concrete with addition of a product rendering concrete waterproof;

- (106) Coating imitating rocks in aquariums in the form of lost formwork or in the port polished concrete elements participating in the resistance and sealing the walls;

- (107) Aquarium.

Figures 9, 1 0 and 1 1 illustrate the principle of assembly of prefabricated elements shown in Figures 8a and 8b. They also give the details of the composition of the walls in mixed steel-concrete structure delimiting the elements which are in direct contact with the sea water.

FIGS. 9 and 10 more specifically represent the bottom of the bridge deck 1 (P1) raft float made of the composite structure described above which is connected to the deck 2 (P2) by means of partitions (CL1) and (CL2) - sails beams providing resistance (and forming the double bottom) and delimiting the ballast tanks (R). The assembly of the prefabricated elements, after adjustment of the drafts (by additional deadweight, ballast or cylinders) is carried out according to the detail of Figures 9 and 10 in the following order:

- assembly of the uprights (1 07) in T by HR bolts (108) (the work area is previously isolated from the rest) and put in butt weld (109) of the sheet (101) with the aid of the adjusting plate (1010);

- setting up complementary reinforcement (105); and

- Concreting the space with waterproof concrete (106).

Advantageously, the pontoons forming pools are shown in Figures 12, 13, 14 and 15 which show perspective views, sections and a plan view. The pontoon beaches consist of:

- (121, 131, 141, 1 51) floating dike protecting the port;

- (122, 132, 142, 1 52) console brackets embedded in the dike; - (123, 133, 143, 153) pontoons made of waterproof reinforced concrete caissons (or other materials) with ballast compartments (134) for draft adjustment and possibly cables (C) with tension control device ( R) (reduction of the vertical movements of the pontoon) connecting the ends of the pontoon to the base of the float;

- (135, 155) Removable stainless steel joints ensuring the articulation of the pontoons on the brackets and allowing the adjustment of draft;

- (E) of Figure 12, reinforced concrete stairs fixed on the brackets supporting the net (126, 146, 156);

- pool bottom made of net (126, 146, 156) supporting the weight of swimmers and protecting them from drowning, sharks and jellyfish;

- (P) Figures 1 3 to 1 5, device for protecting swimming pools against shocks boats and various floating objects and consisting of:

- (157) an upper cable supported by float buoys (159);

- (158) a lower cable suspended on an upper cable and supporting the net (1 56);

- the net placed vertically and fixed on the cables protecting the pool against sharks, jellyfish and oil pollution.

A fifth axis of improvement (A5) concerns the anchoring variant by the replacement of cables and chains by a device of batteries or jacket recessed in the seabed. Figures 16, 17 and 18 give the details of the device. proposed anchorage. Advantageously, the float of the barge, represented in FIG. 8, comprises 16 compartments (X) intended for anchoring, ie four compartments situated under six arms (84) taking up the efforts which are concentrated at the ends of the dikes (85) and ( 86). Advantageously each compartment, shown in Figure 16, comprises a structure for assembling the connecting tubes to be fixed inside the battery tubes providing the connection between the barge and the stacks implanted under the bottom level of the barge. Advantageously, a suitable mounting device makes it possible to raise and lower the sleeve tubes and move them horizontally to adjust them with the implantation of the batteries (Adjustment (R) fig.18). Advantageously different types of Links with jacket batteries can be planned and chosen according to local conditions of implementation of the platform, as follows:

- Perfect non-dismountable installation of piles in the barge structure, either by welding the sleeves with the batteries, or by filling the connecting tubes with concrete with complementary reinforcement ensuring the anchoring, or by both at the same time. times. This device allows to take vertical and horizontal forces (swell + wind + rising water). This simplest solution can be adapted for the Mediterranean Sea for a lifetime of the 100 year old barge;

- Recessing the batteries in the barge, removable and adjustable, using the device (J) shown in Figures 17 and 18;

- Embedding the connecting tube in the batteries by welding and concreting and articulation with vertical sliding of the tube providing the connection with a fitting tube embedded by welding and concreting in the anchoring room (X). This interlocking tube can be coated internally with teflon facilitating vertical sliding (solution to be adopted in the case of large tides taking only the horizontal forces).

Figure 16 shows the horizontal sectional anchorage room A-A of Figure 17, with the barge connection details with the jackets. Are referenced:

- (161) Double steel walls filled with reinforced concrete

- (162) Steel sails welded to the walls and plate of the raft (163)

- (164) Vertical stiffener welded on the connecting tube (T) and on the web (162) after adjustment (R) of the verticality (installation tolerance of the batteries - jackets)

- (165) Welded flange on the tube and on the sheet (163) after adjustment (the opening in the sheet (D1) larger than the tube diameter (T) makes it possible to absorb the imprecision of implantation of jackets The frames of the steel tube piles are filled with reinforced concrete and embedded in the ground by means of drilling (principle of dolphins). Figures 17 and 18 show the assembly detail of the tube connecting the barge with the pile jacket, in vertical section with the details. Are referenced:

- (170) Pressure anchoring room for flushing water

- (170 a) Technical room entrance hall with watertight hatch

- (171) Double steel walls filled with reinforced concrete around the anchorage room

- (173 and 183) Reinforced steel sheet with stiffeners forming the base of the anchorage room

- (172 and 182) Gusset - sail welded to the stiffeners of the tube after adjustment (R) of the alignment

- (174 and 184) Vertical stiffener welded on the tube (T)

- (185) Sheet metal flange welded to the tube (T) and to the plate (1 73 and 183) after alignment adjustment

- (T) Steel tube outer diameter D2 adjusted to the inside diameter of the battery (P)

- (E) Thickness of the walls of the tube

- (J) Connecting tube joint (T) for disconnecting the barge and modifying the draft of the barge in case of rising waters by adding a complementary piece (alternative solution)

- (BR) 2 flanges welded on two sections of the tube recessed by gussets (G1), welded on the flanges and the tubes

- (NE) Neoprene gasket

- (HR) Bolts for clamping and transmitting horizontal forces

- (L) Length of the connecting tube

- (P) Stack of steel tubes filled with concrete (duke of albe forming part of the jacket embedded in the ground)

- (C) Jacket braces (sleepers + diagonals forming with pile a rigid structure)

- (G2) Gusset - funnel to facilitate alignment of tube axes to assembly - (S1) Corner weld of connecting tube to the walls of the jacket stack

- (S2) Plug welds - (B1) Battery concreting stop

- (F) Battery Armature

- (B2) Concreting after completion of welded joints (S1) and (S2)

- (B3) Concreting of compartments of the anchorage room

- (B4) Possible concreting inside the connecting pipe for the realization of non-removable installation subject to the verification of the strength of the structure under the effect of rising waters.

Thus, those skilled in the art appreciate that the structure meets the needs of extension of the activities of the coastal towns lacking land, following the rising waters resulting from global warming, which will lead, in the near future to the flood areas bordering the coast.

The architectural and technical design resulting from the present invention can accommodate several thousand inhabitants while attracting many visitors and customers to live, work and enjoy the various leisure facilities. Such an autonomous, energy-efficient marine city is an innovative example of sustainable development.

Each component of the barge structure provides a plurality of structural, functional, ecological and architectural functions. By concentrating all the activities of a city in a single complex, all the problems of sustainable development and security are more easily and more economically solved than in the habitat along the coast. The new platform - barge designed according to the method of the invention, can be anchored offshore in a water depth greater than 50 meters, and its structure is more resistant to the tsunami that built on the coast.

Thus, the new structure advantageously allows to meet the expected objectives, according to a prefabricated building method that simplifies assembly, reduces the weight, and limits the cost of the barge. The proposed method covers in particular: - the construction of double curvature structures, applied for the dome supporting the solar panels and for the structure supporting the canopy of the atrium;

- the construction of a large float, greater than 100 m, broken down into a number of elements made of a composite steel structure, prefabricated at the factory and assembled on a floating site in a construction site with a shallow draft, while ensuring good sealing and excellent resistance to corrosion;

- the construction of beaches - pontoons, forming swimming pools, fixed on dikes all around the barge, forming bathing areas providing the functions of protection against the shocks of boats and other floating objects, breakwaters reducing nuisance waves, protection of swimming areas, drowning, sharks, jellyfish and oil pollution.

The new structure also covers a device for anchoring the barge in jackets to reduce the movement of the barge in the case of connection with the coastline tunnel and bridge.

Claims

claims

1. Large barge having a dome at the upper part ensuring bracing and supporting photovoltaic and thermal panels for the production of electricity and for heating, the dome forming a composite assembly consisting of:

- a three-dimensional tubular structure prefabricated by slices;

- a bent steel sheet welded on sleepers and chords of the structure; - spot-welded L-stiffeners on the steel sheet;

- an armature of predefined geometry;

light concrete with the addition of a product rendering the waterproof concrete filling the sheet, the stiffeners and the reinforcement; the dome further comprising: - a network of tubes allowing the circulation of a liquid to cool the photovoltaic panels and the three-dimensional structure and heat the water;

- air spaces; and

- panels composed of security glazing and glued photovoltaic cells for the production of electricity.

The barge of claim 1 wherein the three-dimensional structure comprises a dovetail-shaped multidirectional lattice web, the dome being supported by a plurality of legs (27), the structure further comprising a plurality of inclined posts (28). fixed on the lower part of the structure, the structure being characterized in that it is composed of prefabricated slices, each prefabricated slice comprising two curved chords (31), sleepers (32), and diagonals (33).

3. The barge according to claim 2 wherein each leg is a prefabricated slice whose drawings are formed by rotating an arc rotating about a vertical axis of a modular angle equal to 360 / n.

4. The barge of claim 2 or 3 wherein the cross members are square or rectangular tubes, and the diagonals are round tubes.

5. The barge according to any one of claims 1 to 4 wherein the curved members are obtained by rotation about a vertical axis of an arc placed upside down obtained by hot bending the square tubes.

6. The barge according to any one of claims 1 to 5 further comprising a network of water gutters (36) for rainwater recovery.

7. The barge according to any one of claims 1 to 6 wherein the three-dimensional structure has a geometry to support a double glazed atrium canopy.

8. The barge of claim 7 wherein the three-dimensional structure comprises six crutches fixed on the arms of the barge and forty-eight inclined columns, all constituting a rigid assembly for increasing the resistance of the barge.

9. The barge of claim 8 further comprising means for forming a tourist barge.

The barge of claim 9 wherein the means comprises at least:

- A large habitable float steel-concrete composite structure (3), said float comprising prefabricated elements assembled by construction joints;

- pontoon beaches (4); and a system for anchoring the barge (8) in jackets to reduce the movements of the barge.

1 1. A tourist barge comprising a peripheral protection consisting of pontoons forming pools, fixed on dikes all around the barge and connected at the bottom by nets arranged horizontally and on the sea side by cables and nets arranged vertically, such as that all forms swimming areas.

12. The barge according to claim 1 1 in which the pontoon beaches consist of:

- console beaches embedded in the dike;

- Reinforced concrete stairs fixed on the brackets supporting the net;

- a pool bottom made of net supporting the weight of swimmers and protecting them from drowning, sharks and jellyfish; and

13. A barge according to any one of claims 1 to 12 comprising an anchoring device for reducing the movements of the barge under the effect of external loads, the anchoring device being characterized in that the fixing of the barge is made either on piles of tubes drilled and embedded in the ground and filled with reinforced concrete, or on jackets using a device allowing the horizontal and vertical adjustment, allowing the assembly and the disassembly of the barge, and allowing a modification of the draft of the barge according to the rising waters.

14. A barge according to claim 13 wherein the barge comprises a float large living space that has sixteen compartments for anchoring, four compartments being located under six arms taking the efforts concentrated at the ends of dikes.

15. The barge of claim 14 wherein each compartment comprises a structure for assembling connecting tubes to be fixed inside the battery tubes providing the connection between the barge and the stacks implanted below the bottom level of the barge.

16. The barge of claim 1 3 wherein the mounting device allows up and down sleeve tubes and move horizontally to adjust with the implantation of batteries.

17. A method of constructing a barge according to any one of claims 1 to 1 6 characterized in that it comprises steps of construction of a large float steel-concrete composite structure, consisting of:

- to carry out in a plant prefabricated elements for the float, each element being decomposed into several prefabricated sections, the dimensions of which are chosen according to the type of transport used between the plant and an assembly yard, and where each prefabricated element coming into direct contact with seawater consists of a mixed steel-concrete structure; and

- to assemble the prefabricated elements by construction joints.