FR2807459A1 - SELF-SUPPORTING STRUCTURE CONSISTING OF SPHERICAL TRIANGULAR PANELS AND VAULTS, IN COMPOSITE MATERIALS, WHICH ASSEMBLE BY CLIPPING, WITH THE INTERPOSITION OF A SEALING AND POSITIONING GASKET - Google Patents

Abstract

The invention concerns a self-supporting structure consisting of spherical or curved triangular panels, made of composite materials, clipped together, with an interposed sealing and positioning joint. Said structural system enables to obtain light and resistant dome and vault shapes, simply and rapidly mounted, dismountable, easy to maintain, by repetitive assembly of 1 to 3 models of different panels for a common sphere radius. Said panels with spherical triangular shape, correspond to regular cut out polyhedral shapes. They are assembled to constitute domes of different dimensions. The panels are made of plates (1) of plastic materials with warped surface, bonded, welded or built-in in arcuate frames made of alveolate or metallic thermoplastic extruded profiles, linked together by a sealing and positioning joint (3), fixed with metallic clips (4) distributed at the panel jointing. With 75 spherical triangular panels of less than 2 meters in width, having a weight of 15 kg, can be constructed a dome 4 meter high covering 66M<2> on the ground, wholly or partly transparent, having a weight of about 1200 kg. With 6 panels, 10 M<2> can be covered.

Description

The present invention relates to a construction system making it possible to obtain self-supporting structures in the form of domes and vaults, for the manufacture of swimming pool enclosures, verandas, annexes to the dwelling, living rooms, multipurpose rooms, rooms. multimedia, kiosks, constructions for professionals, such as offices, meeting rooms, fitness rooms, roof domes, skylights, ...

Traditionally, domes are made with very heavy conventional materials, such as reinforced concrete, curved laminated glass panels held by metal frames. They are made to measure, according to very expensive architectural plans, which makes them suitable for prestigious buildings, museums and other public buildings. These traditional domes constructions are too expensive and too complex to implement for current use by individuals, local communities and businesses. There are also veranda systems manufactured with PVC profiles, but which must be reinforced by metal frames to improve the mechanical strength and reduce the buckling of the panels formed, especially these verandas or swimming pool enclosures are made with laminated glass in general plan, heavy weight, which must be kept in place with a complex and expensive assembly comprising gaskets.

construction system according to the invention makes it possible to obtain self-supporting structures in the form of domes and vaults, light, resistant, easy to maintain, which blend harmoniously into the environment, made of composite materials, at attractive costs, which can be quickly and easily assembled, which can be dismantled, for private and professional use, with many possible combinations and arrangements. The new shapes and functions obtained are not achievable at competitive costs with traditional materials.

high resistance for a low weight is obtained by combining several characteristics, namely: frames in honeycomb PVC profile, which have good flexural strength for a very low weight and made up of 3 elements welded to the mirror.

Rigid assembly by collagelsoldering the interior triangle panel to the frame. spherical shaping of the triangle assembled flat, by a suitable process, based on perfect control of the thermal process, which guarantees good stabilization over time of the panel thus formed with very low temperature expansion.

- spherical shell shape and vault which considerably reduces buckling and deformation at equal stresses compared to a flat structure of the same thickness and same surface, thus accepting much greater loads (snow, wind resistance). self-supporting structure in the shape of a dome or vault, is obtained from panels in the shape of spherical triangles corresponding to the cutting of a regular polyhedron, and therefore requiring few different panels for the same radius sphere. They constitute domes of different dimensions depending on the number of spherical triangles assembled, such as spherical "hexagon" triangles and spherical "pentagon" triangles, of the truncated icosahedron, making it possible to make different sizes of domes, and up to the complete sphere. achievable with 180 spherical triangles 2 models. The dodecahedron makes it possible to make a complete sphere with 60 identical spherical triangles. The "icosidodecahedron" allows to realize a complete sphere with 80 spherical triangles of 2 models. The dodecahedron snub allows you to make a complete sphere with 140 spherical triangles of 2 models. The "rhombicosidodecahedron" makes it possible to make a complete sphere with 200 spherical triangles of 3 models. You can also cover a kiosk with the assembly of a few spherical triangles of the same model.

The spherical triangles consist of plates of plastic materials, preferably of polymethyl methacrylate (PPMA) or polycarbonate (PC) or other thermoplastic, transparent or opaque, shaped to the left by bubbling thermoforming using suitable tools. The opaque plates can also receive thermal insulation and a finishing coating, fixed on the concave inner face.

thermoplastic profile serves as a frame for the panel, it is preferably rigid, honeycombed, extruded, based on a polymer compound. The shape of the section studied to allow hot bending with a regular curvature, along a longitudinal axis, without any other apparent deformation.

sealing and positioning seal, made of elastomer, is inserted between spherical triangles during assembly. It is profiled to be able to be put in place and withdraw from the interior side of the structure. It allows the easy assembly and disassembly of a panel of the structure, and comprises lips in the form of a mini-gutter to recover and evacuate any water leaks from inside the structure.

Metal fixing clips are put in place by simple pressure to snap into grooves of the profile provided for this purpose. They exert pressure to hold the panels together through the seal described above and are distributed along the adjacent edges. They can be removed by levering them using a simple screwdriver inserted into a hole placed laterally.

The assembly is completed by sealing elements arranged at the intersection nodes of the profile frames surrounding the spherical triangles. The 3 vertices of the triangles are previously cropped for this purpose. This node is formed by a cup of flexible material, preferably of elastomer or flexible PVC, which is put in place by deforming from the inside, with a pasty seal deposited on the periphery and which obstructs the orifice after positioning and tightening of a suitable fixing. The pasty seal once in place and crushed, polymerizes and hardens on contact with air. everything is completed by a spongy material and a perforated washer which ensure recovery, then evacuation, by evaporation of any micro-water leaks drained by the lips of the seal.

Particular panels can be put in place, acting as access doors and patio doors, with side opening. They are arranged on the periphery in the characteristic shapes of polyhedra, such as pentagons or spherical hexagons, with appropriate frames in the form of small spherical triangles to reinforce the structure and adapt the size of the openings. Elastomeric gaskets are fixed vis-à-vis the profiles to ensure the sealing of the opening panels between them and with the frames. Likewise, spherical triangles can be mounted so that they can open like skylights, casement windows or roof windows.

self-supporting dome-shaped structure thus formed rests on a base made of composite materials. The junction is made between the cutting of the spherical triangles of the self-supporting structure and a flat surface which can be the floor, a vertical or oblique wall. Technical reserves are planned for the door steps, fixings, waterproofing, water recovery, and others.

curved panels manufactured using the same process make it possible to produce sections in the form of cylindrical vaults which can be connected to structures in the form of dores of the same radius and complementary to the spherical triangles to form homogeneous units.

dome made up of 6 spherical "hexagon" triangular panels, covering a framework fixed to the ground, makes it possible to create kiosks, shelters, as well as large covered spaces, obtained by juxtaposing as many hexagonal shelters as necessary by the 'Intermediate "beams / gutters" supported by "tubes / posts" also serving for the evacuation of rainwater in a network of pipes on the ground arranged directly above the "gutter beams".

accompanying drawings illustrate the invention: Figure 1 shows a sectional view of the assembly of 2 panels in the form of spherical triangles of the structure, in the axis of the profiles which constitute the frame. FIG. 2 represents the section of the profiles which constitute the frame of the panels in the form of spherical triangles, with the fixing system by gasket and clips.

Figure 3 shows the securing clips in perspective.

FIG. 4 represents a view in section at the level of an assembly node of the panels in the form of spherical triangles.

FIG. 5 represents a section of the installation by deformation, the sealing cup at the assembly node of the panels in the form of spherical triangles.

FIG. 6 represents a partial view of the self-supporting structure with several panels in the form of assembled spherical triangles, and the location of the junction nodes.

Figure 7 shows a small dome made up of 6 panels in the form of spherical triangles.

FIG. 8 represents a dome made up of 15 panels in the form of assembled spherical triangles.

FIG. 9 represents a dome made up of 65 assembled spherical triangular shaped panels and 5 French doors with 2 leaves on the periphery.

FIG. 10 represents one of the 5 elements of the base which supports the self-supporting structure shown in FIG. 9.

FIG. 11 represents elements in the form of a vault assembled and attached to a self-supporting semi-sphere structure.

Figure 12 shows a system of closing joints which fits opening profiles.

FIG. 13 represents a kiosk made with 6 panels in the form of spherical triangles.

FIG. 14 represents the assembly of several kiosks made with panels in the form of spherical triangles, constituting a hall.

With reference to these drawings, the self-supporting structure in the form of an arch dome is obtained from panels in the form of spherical triangles corresponding to the cutting of a regular polyhedron, and thereby requiring few different panels for the same radius of the sphere. They constitute domes of different dimensions depending on the number of spherical triangles assembled, such as spherical "hexagon" triangles (13) and spherical "pentagon" triangles (14), of the truncated icosahedron, allowing different sizes of domes to be made, and up to the complete sphere achievable with 180 spherical triangles of the 2 models. The spherical triangles consist of plates (1) made of plastic materials, preferably polymethyl methacrylate (PPMA) or polycarbonate (PC) or other thermoplastic, transparent or opaque, shaped to the left by bubbling thermoforming using suitable tools. The opaque plates can also receive thermal insulation and a finishing coating fixed on the concave interior face.

A thermoplastic section (2) serves as a frame for the panel, it is preferably rigid PVC, honeycombed, extruded, based on a polymer compound. The shape of the section designed to allow hot bending with a regular curvature, along a longitudinal axis, without any other apparent deformation.

A sealing and positioning seal, made of elastomer, is inserted between the spherical triangles during assembly. It is profiled so that it can be set up and withdrawn from the inside of the structure. It allows easy assembly and disassembly of the structure panel, and comprises lips (5) in the form of a mini-gutter to recover and evacuate any water leaks from inside the structure.

Metal fixing clips (4) are put in place by simple pressure to snap into grooves (6) of the profile (2) provided for this purpose, by exerting pressure to hold the panels together via of the seal described above. They can be removed by levering them using a simple screwdriver inserted into an orifice (7) placed laterally.

The assembly is completed by sealing elements arranged at the intersection nodes of the profile frames (2) surrounding the spherical triangles. The 3 vertices of the triangles are previously cropped for this purpose. This node is formed by a flexible material cup, preferably in elastomer or flexible PVC, which sets up and deforms from the inside, with a pasty seal (9) deposited on the periphery which obstructs the orifice after positioning and tightening of a suitable fixing. pasty seal (9) once in place and crushed, polymerizes and hardens on contact with air. everything is completed by a spongy material (11) and a perforated washer which ensure the recovery and evaporation by evaporation of any micro-water leaks drained by the lips (5) of the seal (3).

Particular panels (15) and (16) can be put in place, acting as access doors and patio doors, with side opening. They are arranged on the periphery in the characteristic shapes of polyhedra, such as pentagons or spherical hexagons, with appropriate frames (17) in the form of small spherical triangles to reinforce the structure and adapt the size of the openings. Elastomeric gaskets (22) and (23) are fixed vis-à-vis the profiles (2) to ensure the sealing of the opening panels (15) and (16) between them, and with the frames (17) . even, spherical triangles can be mounted so that they can open like skylights, casement windows or roof windows.

The self-supporting dome-shaped structure thus formed rests on a base (18) made of composite materials, obtained by co-projection of glass fiber polyester resin onto a form, or injected into a mold. The junction is made between cutting the spherical triangles of the self-supporting structure and a flat surface can be the floor, a vertical or oblique wall. Technical reserves are planned for doors, fixings, waterproofing, water recovery, and others.

curved panels (19) manufactured using the same process make it possible to produce sections in the form of cylindrical vaults (20) which <B> can </B> be connected to structures in the form of domes (21) of the same radius and complementary to the spherical triangles to form homogeneous sets.

A dome made up of 6 spherical "hexagon" triangular panels (13), covering a framework (24) fixed to the ground, makes it possible to create kiosks, shelters, as well as large covered spaces, obtained by juxtaposing as many hexagonal shelters as necessary by means of "beams / gutters" (25) supported by "tubes / posts" (26) also serving for the evacuation of rainwater in a network of pipes on the ground arranged plumb "gutter beams" (25).

The self-supporting structures obtained from panels in the form of spherical triangles and in the form of arches, which are assembled by clipping with a sealing and positioning joint, allow a large number of lightweight constructions to be produced, a non-exhaustive list of which is given below: Swimming pool shelters, Garden shelters, verandas, greenhouses, annexes to housing, living rooms, fitness and sports rooms, multipurpose rooms for individuals and communities, multimedia rooms, "home cinema" , creative workshop, work, meeting rooms, training, seminars, offices, treatment and rest areas, kindergartens, discos, barslrestaurants, swell club for sports complexes, airports, bungalows for holiday villages ,.

For "construction", roof domes, skylights, indoor spaces covered with skylights, kiosks, exhibition halls, shops.

Self-supporting structures rotating on a ring of water, or on a runway arranged on the periphery, to adapt to climatic conditions: Bioclimatic space. For these embodiments, the panels in the form of spherical triangles are preferably made with dimensions close to 2 meters per side, for a weight of about 15 kg with a skin thickness of 5 mm, 20 kg for a skin thickness of 8 mm.

The surface covered with a dome made up of 75 panels in the form of spherical triangles with a radius of 4.75 meters, is 60 M2 on the ground, for meters high. The panels are all or part transparent or opaque, which represents a total weight of around 1200 kg for the dome. With 6 panels, we cover 0 M2, for a weight less than 100 kg. The dodecahedron makes it possible to make a complete sphere with 60 identical spherical triangles. The dodecahedron "snub" allows you to create a complete sphere with 140 spherical triangles of 2 models. The "rhombicosidodecahedron" allows to realize a complete sphere with 200 spherical triangles 3 models. You can also cover a kiosk by assembling a few spherical triangles of the same model. For panels in the form of spherical triangles, corresponding to an "icosidodecahedron" (regular polyhedron broken down into 12 pentagons, themselves broken down into 60 triangles, and 20 equilateral triangles, in total 80 spherical triangles) and for a sphere radius of 3 meters , we obtain a half-spherical dome made up of 40 triangles, covering a living area of 19.6 M2, taking into account a 400mm pit. The weight of this structure is around 600kg. By inserting panels in the form of cylindrical vaults of dimensions and radius compatible with the spherical triangles constituting the hemispheres, modular structures are obtained, as illustrated in figure 11.

panels in the shape of spherical triangles, the compatible panels in the shape of cylindrical vaults, the elements that constitute the junction bases with a flat surface, and all the accessories necessary for assembly (sealing and assembly joints, clips, nodes) , are delivered in a professional kit, for the realization of a predetermined self-supporting structure. The panels should not exceed a weight of 25 kg for an average of 10 to 20 kg, which allows easy and quick assembly from the inside, only one person. The spherical and cylindrical radii provided for the main families of elements are: 3 meters - 4.75 meters - 6 meters. Other radii beyond 2 meters are possible, with a limit which is around 10 meters in this technology, which makes it possible to produce single-piece domes that can cover up to 250 M2 of surface area. . A structure can be dismantled, and it is also possible to replace one or more panels if necessary for maintenance.

Claims (1)

<B> CLAIMS </B> 1 System for the construction of self-supporting structures, characterized in that the constituent panels are plates (1) of plastic materials with a left surface, glued or welded to frames made of honeycomb thermoplastic profiles (2), curved, interconnected by means of a seal (3) for sealing and positioning, with a fixing by metal clips (4) distributed along the adjacent edges of said panels, all assembled, constituting shapes of domes and vaults, light and resistant in composite materials. 2 System for the construction of self-supporting structures according to claim 1, characterized in that the plates (1) of plastic materials are preferably made of polymethyl methacrylate (PPMA) or polycarbonate (PC) or other thermoplastic, transparent or opaque and shaped left by thermoforming or bubbling from suitable tools, the opaque plates can also receive thermal insulation and finishing coating on the concave inner face. 3 System for the construction of self-supporting structures according to claim 1, characterized in that the thermoplastic profile (2), serving as a frame for the panel, is preferably rigid PVC, honeycombed, extruded, based on a polymer compound, the shape of which of the section is designed to allow hot bending with a regular curvature, along a longitudinal axis, without any other apparent deformation. 4 Self-supporting structure construction system according to claim 1, characterized in that the seal (3) for sealing and positioning, made of elastomer, profiled to be able to be put in place and withdrawn from the inside of the structure, allowing thus the assembly and disassembly of a panel of the structure and comprises lips (5) in the form of a mini-gutter to recover and evacuate any water leaks. 5 Self-supporting structure construction system according to claim 1, characterized in that the metal clips (4) for fixing are placed by simple pressure to snap into the grooves (6) of the profile (2) by exerting pressure to hold the panels together, and can be removed by levering in the hole (7) using a simple screwdriver. 6 System for the construction of self-supporting structures according to the preceding claims, characterized in that the assembly is completed with sealing elements arranged at the intersection nodes of the frames in profiles previously trimmed for this purpose, constituted by a cup (8) in flexible material, preferably in elastomer or flexible PVC, which is put in place by deforming from the inside, with a pasty seal (9) deposited on the periphery and which obstructs the orifice after tightening of the binding (10), polymerization, hardening in contact with air, the whole supplemented by a spongy material (11) and the perforated washer (12), ensuring the recovery, then the evaporation by evaporation of any micro-water leaks drained by the lips (5) seal (3). 7 - System for the construction of self-supporting structures according to the preceding claims, characterized in that the panels which constitute said structure have shapes of spherical triangles corresponding to the regular polyhedron cutting, by the same requiring different panels for the same radius of the sphere, being able to constitute domes of different dimensions according to the number of spherical triangles assembled, such as spherical "hexagon" triangles (13) and spherical "pentagon" triangles (14), of the truncated icosahedron, allowing the manufacture of different sizes of domes, for a sphere complete realizable with 180 spherical triangles of the 2 models, the dodecahedron for a complete realizable sphere with identical spherical triangles, "the icosidodecahedron" for a complete realizable sphere with 80 spherical triangles of 2 models, the dodecahedron "snub" for a complete realizable sphere with 140 spherical triangles of 2 models, the "rhombicosidodecahedron" for a complete sphere achievable with 200 spherical triangles of 3 models. 8 - System for the construction of self-supporting structures according to the preceding claims, characterized in that the assembly is completed by particular panels (15) and (16) serving as access doors and patio doors, with lateral opening, arranged on the periphery and forming part of the characteristic shapes of polyhedra, such as spherical hexagon pentagons, with frames (17) in the form of small spherical triangles to strengthen the structure and adapt the size of the openings, with elastomeric seals (22) and (23) coming to be fixed vis-à-vis the profiles (2) to ensure the seal between the opening panels (15), (16) and the frames (17). 9 - System for the construction of self-supporting structures according to the preceding claims, characterized in that the assembly is completed by a base (18) made of composite materials, which provides the junction between said self-supporting structure in the form of a dome, according to the cutting of the spherical triangles, and a flat surface which can be the ground, a vertical or oblique wall, with technical reserves for door steps, fixings, waterproofing, water collection, and others. 10- System for the construction of self-supporting structures according to the preceding claims, characterized in that the assembly is completed by curved panels (19), according to the same process, which make it possible to produce sections in the form of cylindrical vaults (20), which arches can be connected to structures in the form of domes (21) of the same radius and complementary to the spherical triangles to form homogeneous sets. 1 System for the construction of self-supporting structures according to claims 1 to 7, characterized in that a dome consisting of 6 triangular "hexagon" spherical panels (13), covering a frame (24), fixed to the ground, makes it possible to achieve kiosks, shelters, as well as large covered spaces, obtained by juxtaposing as many hexagonal shelters as necessary by means of "gutter beams" (25) supported by "tubes / posts" (26) also serving for the evacuation of rainwater in a network of pipes on the ground arranged plumb "beams / gutters" (25).