WO2006018564A1 - Assembling and arrangement flat element consisting of one or several elements - Google Patents

Abstract

The assembling element defining a plane (P) comprises primary and secondary structures which are positioned substentially in parallel to the plane (P). Said primary structure comprises at least two separate beams (2) each of which is provided with boards (3) having a rectangular cross-section, parallel with respect to each other and placed on an edge along the longitudinal axis (L) thereof parallel to the plane (P) of the building element (1), wherein one or several boards are laterally (4) offset in a perpendicular direction to the plane (P) and at least two boards which are not laterally offset. The secondary structure (9) connects the separate beams (2) to each other by the internal edges of at least two boards which are not laterally offset.

Description

 ELEMENT CONSTRUCTION PLAN AND ARRANGEMENT FORMED FROM ONE OR MORE ELEMENTS

The present invention relates to a construction plane element. The invention also relates to an arrangement for a construction, which is formed from one or more planar elements.

In the field of construction, taken in its broad sense, the wood is more and more used for the realization of various works. The evolution of the transformation and prefabrication processes, as well as the interest of using wood, in relation to the sustainable development objectives, give wood constructions a particular advantage. The wood will also be associated with other materials, such as concrete, polymeric materials, metals, glass, and others. However, the architectures and high-performance systems developed industrially must be: prefabricated, to reduce assembly time on sites, multifunctional, to save on the number of layers needed and serve as indoor or outdoor architectures, - perfectly controlled for all mechanical characteristics, for fire resistance, for acoustics, and for subsequent implementations (for the insertion of other elements, such as ducts, etc.), users an ecological and economic base material, such as solid wood board, - easily dismountable, if necessary, for example in the context of temporary constructions, to take account of ecological constraints requiring reuse of the materials used in such a framework, and very competitive from a price point of view.

For example, the field of slabs is in a strong evolution, based on the use of massive dried boards, massive solid system or mixed wood associated with bound concrete, to reach large spans. Prior art

Large arrangements such as horizontal slabs, platforms suspended or mounted on piles, vertical walls, can withstand significant fixed or moving loads, have already been realized. Document DE-1 609 888 discloses a floor structure comprising a primary structure, made from parallel longitudinal plates, at the two ends of which are placed several slats, so as to give an I-section. The longitudinal plates form a central core , making the thickness of the floor, thus giving its inertia, and are reinforced in compression and traction by unitary or plural smooth, symmetrical on the upper part and the lower part. A floor structure maintained by secondary beams comes to rest on the plates.

The document PL-170.890 describes a structure made from parallel planks, held laterally by crosspieces arranged in X. A horizontal plate intended to maintain an upper concrete layer is placed between two parallel planks.

EP-1.323.876 discloses a box made from two substantially parallel plates, connected by longitudinal crosspieces arranged in a cross. The braces are inserted in an upper longitudinal lath for compression forces, provided at the upper plate, and in a lower longitudinal lath for tensile stresses, provided at the lower plate.

WO-02 / 31-283 discloses a prefabricated floor element consisting of a box incorporating an upper panel with crossed folds, serving as a compression yoke. The upper panel is placed on several central boards, whose base incorporates one or two staggered slats. These central boards serve as spacer to give the inertia of the box.

This system is only a simple prefabricated box, and allows no other variation than the box presented, with boards and panel. The central board, with its or its laths, does not form a beam. Indeed, without the upper panel necessarily rigidly connected, the box has a performance that is substantially equal to the inertia of the central boards. The two side slats do not reinforce the beam for itself. The panel must even be cut to integrate the head of the board and to be able to form an indissociable whole. The document DE-195.37.298 describes a wooden arrangement consisting of a succession of parallel boards, arranged vertically, being alternately and slightly offset in the vertical plane, to build self-supporting roof panels. These panels are at the same time the internal framework of the volume located under the roof. However, the charges received must be well distributed and the resulting ranges remain low, of the order of 3 m to 5 m.

To reach larger litters, we know from the document

FR-2,777,112, the association of a layer of poured concrete on boards arranged vertically and slightly offset in the vertical plane, to be able to receive a transverse connector, blocking the concrete on the wood. With this arrangement, spans of 7 m to 8 m are possible, for standard slab loads equal to 300 kg / m ² .

For example, to reach large spans with massive planks arranged on edge, the document EP-1.149.213 discloses parallel planks, arranged on edge, with an opening of the gap between the staggered planks, going to the technical limits of the composed section. The thickness obtained for the arrangement makes it possible to considerably increase the free span without requiring intermediate support. An upper panel stabilizes the boards against the spill and is the floor of the upper floor.

However, the great limit of these arrangements is that, with equal area, they prove to be extremely wood-consuming, for relatively limited ranges, from 5 m to 9 m. The large amount of wood needed adds weight to the layout and overall construction.

In addition, these arrangements used as a slab, do not allow to house the usual ducts and ducts of the building (water circulation network, ventilation ducts and air conditioning, electricity, etc.). Moreover, during the implementation of these massive arrangements in dried planks, if heavy rains come to moisten the wood, boards of boards swell like a sponge. This phenomenon generates major disorders in the building, either by exerting a push on the walls, or by tiling to absorb the transverse expansion.

Presentation of the invention

A main problem to be solved by the invention is to develop a construction element, able to form a horizontal slab type arrangement or vertical wall, which is both simple and economical in terms of the amount of boards needed. A second problem is the realization of an element, allowing, from its design, to have passages or unoccupied volumes, for the insertion of ducts, pipes, wiring of a building. A third problem is to design a plane element from wood, having good abilities to absorb mechanical deformations. A fourth problem is obtaining a two- or three-dimensional arrangement incorporating one or more planar elements.

In known manner, a building element, defining a plane, comprises a primary structure and a secondary structure substantially parallel to the plane.

According to the invention, the construction element is characterized in that: the primary structure has at least two distinct beams, each having rectangular section boards parallel to each other, arranged on edge, with their longitudinal axis parallel to the plane the building element, with one or more planks offset laterally perpendicular to the plane, and at least two planks not offset laterally; and in that the secondary structure connects each of the separate beams to one another at the level of the inner edges of at least two of the boards that are not offset laterally.

In other words, a separate beam, formed from at least two staggered boards, constitutes a primary structure of high performance. These beams, with the particular arrangement of their planks, are concentrated structural elements. The boards of each beam are offset laterally, that is to say relative to their width. On the other hand, if the boards inflate because of the humidity of the site, it is no longer a problem since they have the entire empty area on each side to expand.

The association of the beams with the secondary structure constitutes the plane element. The presence of the secondary structure above all the plank beams, absorbs the mechanical stresses exerted on the element thus formed. The planar member may include a plate that can be maintained by the two face-to-face boards, each located at the edge of each of the adjacent separate beams. The plate can be freely arranged at different levels. The plate, the boards and the secondary structure delimit a closed volume, constituting a box. These plates have an architectural function, for example for the rendering of the ceiling, and sometimes technical, in the acoustic field or fire resistance.

By interior, we understand that it is the side facing the boards that are not shifted or to the secondary structure. By outside, it is understood that it is the side facing the boards which are offset with respect to the general plane of the element or the opposite of the secondary structure.

In a first embodiment, the element may comprise a connecting plate between two adjacent adjacent beams, fixed on the inner edge of the two laterally offset face-to-face boards, each located at the edge of each of the adjacent separate beams. In another embodiment, the element may comprise a connecting plate between two adjacent adjacent beams, fixed on the outer edge of the non-laterally offset face-to-face boards, each located at the edge of each of the adjacent separate beams. In yet another embodiment, the element may comprise a connecting plate between two adjacent adjacent beams, fixed on the outer edge of the laterally offset face-to-face boards, each located at the edge of each of the adjacent separate beams. In a last embodiment, the element may comprise a connecting plate between two adjacent adjacent beams, fixed on the inner edge of the two non-laterally offset face-to-face boards, each located at the edge of each of the separate adjacent beams. . The building element may comprise a connecting piece between two adjacent adjacent beams, which can be fixed on the visible face of the two face-to-face boards laterally offset. This connecting piece can be formed from an alternation of boards and spacers offset laterally perpendicularly to the plane. These boards and spacers give the connecting piece a crenellated appearance, substantially similar to the appearance of the beams with alternating boards offset and not offset.

The construction element may also comprise a connecting piece between two adjacent adjacent beams, fixed on the visible face of the two planks. face-to-face not laterally offset. This connecting piece can be formed from boards offset laterally perpendicularly to the plane and positioned at different heights stairs. These staggered boards give the connecting piece a crenellated appearance in steps. Advantageously, the beams may comprise an upper blade, which is fixed on the inner edge of the boards not offset laterally. In another advantageous arrangement, the beams may comprise a localized layer of concrete, with a precise layout, which is poured by filling the spaces delimited by the non-laterally shifted planks and the inner edge of the laterally offset planks.

Very preferably, the beams may comprise a regular alternation of laterally offset planks and non laterally offset planks. For excellent mechanical strength, each of the beams may comprise an odd number of boards. Preferably, the secondary structure may be a distribution panel or a series of slats or others, fixed on the inner edge of the boards not offset laterally or on the localized layer of concrete or on the upper blade. This secondary element structure, for example for floor, which is made of panel or beams or squares or laths, must be continuous on the primary beams, so as not to introduce torsion of the main beams, when a concentrated local load is applied between two beams.

The secondary structure may also be preferably a concrete layer cast on the plate and covering the separate beams. In this way, this high performance beam made of several base planks can be reinforced by a layer of bonded concrete, arranged in the upper part to reinforce the compression zone.

The construction element may favorably include a plurality of connectors inserted into each separate beam perpendicular to the longitudinal axis of the planks. In this case, the connection for securing the two materials, wood associated with concrete, is a transverse connector wood or metal. The boards may be alternately offset by a distance substantially between 30% and 200%, relative to the size of the crossing zone between these boards. The separate beams can join together, so as to allow aesthetics of the element and the arrangement that can be obtained, or a three-dimensional configuration. Thus, the plates may have a substantially triangular, rhombic or quadrilateral shape. According to a second aspect of the invention, an arrangement is formed from one or more elements, as described above, and is characterized in that it constitutes a floor, a ceiling, a farm, a wall anti-noise, forming elements of partitions, walls or separations, slabs, flat or single-slope or double-slope roofs, bridge decks, and others.

Brief description of the figures

The invention will be better understood and its various advantages and different characteristics will become more apparent in the following description, of the nonlimiting example of embodiment, with reference to the accompanying diagrammatic drawings, in which: - Figure 1 represents a perspective view of the below a construction element according to a first embodiment; Figure 2 shows a side view of the construction element according to

Figure 1 ;

Figure 3 shows a cutaway perspective view of the top of a building element according to a second embodiment;

Figure 4 shows a cutaway perspective view of the top of a building element according to a third embodiment; Figure 5 shows a side view of the construction element according to Figure 4; Figure 6 is a perspective view from below of a construction element according to a fourth embodiment;

Figure 7 shows a side sectional view of a building element according to a fifth embodiment;

Figures 8 to 11 show a cutaway perspective view of the top of a construction element, respectively according to the sixth, seventh, eighth and ninth embodiments; Fig. 12 is a side sectional view of a construction element according to a tenth embodiment; Figure 13 is a side sectional view of a construction element according to an eleventh embodiment; Fig. 14 is a side sectional view of a construction element according to a twelfth embodiment; Figure 15 is a bottom view of a ceiling type arrangement formed from a construction element; Fig. 16 is a partial perspective view of a firm type arrangement formed from a construction element; and Figure 17 is a side view of an anti-noise arrangement formed from a building element.

Detailed description of the invention

As shown in Figures 1 and 2, and in a first embodiment of the invention, a construction element (1) has a general plane (P), here substantially horizontal. The building element (1) comprises a plurality of primary structures or beams (2) consisting of five boards screwed together (3). The boards (3) have a rectangular section. The boards (3) are assembled parallel to each other. The boards (3) are arranged on edge. The longitudinal axis (L) of the boards (3) is parallel to the plane (P) of the construction element (1). Of these five boards (3), one board out of two is alternately laterally offset, that is to say with respect to the width of the board (3), relative to each other, perpendicular to the plane ( P) of the element (1). Thus, three boards (4) are shifted down, and two boards (6) are not shifted. The three offset planks (4) enclose the two non-shifted planks (6), at a crossing zone (5).

The prefabrication of a beam (2) is done by connectors, screws or nails or pins, metal or wood, or by gluing. In general, screws are preferred over other types of connectors. The beam (2) consists of an odd number of boards (3), five to seven boards (3), or more, N boards (4), arranged on edges, and screwed, shifted to the maximum of possibilities, and N - 1 boards not shifted (6) or N + 1 boards not shifted. The offset between the boards (4 and 6) is approximately 30% to 200% offset from the contact area and crossing (5) between offset and non-shifted boards (4 and 6) which receives the connectors. The basic materials for the construction of the beams (2) are solid planks, laminated planks (duo or trio or reconstituted solid wood), glulam or microlame panels also called LVL (for Laminated Veneer Lamber) or plywood or also panels called OSB® (Oriented Strand Board) or any other type of beams, based on wood or wood or wood-based reconstituted, and others. It should be noted that these beams (2) can be completely prefabricated in the factory for better quality and for a dry construction on site extremely fast.

A plate (7) or ceiling panel is placed and fixed on the inner edge (8) of the offset plate (4) located at the edge of the beam (2) and thus facing the corresponding offset plate (4) located bordering the adjacent corresponding beam (2). The construction of a plane element (1) is made from the preceding beams (2), which occupy about 10% to 50% of the surface, alternating with the non-structural areas of the plates (7). The plates (7) delimit a box for the passage of ducts and other tubings. This element (1) constitutes a "high ceiling", showing the constituent beams (2). The plates (7) make the interior finish of the lower volume. For these plates, ceiling panels or siding (7), traditional plywood panels are possible. But also synthetic panels or rigid insulation (rockwool for example) for acoustic absorber functions, or openwork lattice panels for architectural aspects and allow permeability of the ceiling (hot air flow, ventilation, loudspeaker, commercial, etc.). For fire resistance, these plates (7) may be chosen in a non-flammable material, class MO, nonflammable, or Ml, hardly flammable.

According to the invention, a secondary structure constituted by an upper floor panel or a distribution panel (9) is placed on the inner edges (11) of the non-shifted planks (6). The continuity of this panel (9) makes it possible to load in an almost equal manner the different non-shifted upper boards (6) of the beam (2). In such a case, the distribution panel (9) associated with the element (1) is preferably constituted by a wooden panel, preferably of the "crossed microlam" type, has a strong axis in the direction of the fibers and a weak axis in the direction of two or three folds crossed. This panel (9) is screwed on the separate beams (2), in continuity on these same beams (2).

It should be noted that the panel (9) of secondary structure floor is dimensioned, to be able to carry this distributed or concentrated load, when it is applied between the two primary beams (2). All the variants presented below are of the same performance, with for example boards of 50/200 mm, shifted by 120 mm, a beam rate of 30% (1/3). The plane element (1) obtained has a bearing capacity of 6 m to 8 m for a load of 300 kg / m ² .

In a second embodiment of the invention (see FIG. 3), the same solution as that of the first embodiment (1) is chosen for an element (12), with the beams (2), the three offset plates (4) and the two non-shifted boards (6) that compose them, and the interposed plates (7). The upper floor panel (9) is completed by an acoustic absorber (13) placed on the floor panel (9), plus a finishing layer (14) constituting the finished floor of the upper volume.

In a third embodiment of the invention (see FIGS. 4 and 5), an element (16) comprises the beams (2), substantially similar to that of the first and second embodiments (1 and 12). ). However, the alternation of the constituent boards (3) has been reversed. Three non-shifted boards (17) wedge two staggered boards (18). The splitter panel (9) is placed on the inner edges (11) of the non-shifted boards (6).

The ceiling box is made with a plate (19), suspended at the lower level, on the outer edge (21) of the upper non-shifted side plate (17) of the beam (2). In this embodiment (16), the beam (2) remains projecting relative to the box plate (19). Two mounting solutions are preferred, with the clip described in EP-1.000.207, which allows an invisible fixation, or with a triangular batten (22), acting as a cover for the connector and which has a small cornice in the visible ceiling. The other usual fixations are of course possible.

In a fourth embodiment of the invention (see Figure 6), an element (23) similarly takes over the first and second embodiments (1 and 12). The beams (2) comprise two non-shifted boards (6) and three shifted boards (4). The secondary structure with a distribution panel (9) is placed on the inner edges (11) of the non-shifted boards (6). The plate (24) is suspended at the lower level, on the outer edge (26) of an additional offset lateral bottom plate (27), which is contiguous to the offset planks (4) bordering the beam (2). This has the effect of hiding the height of the beam (2), and thus to give a more flat ceiling. Other solutions may be adopted to secure the plate (24). Edges or grooves may be provided in the board. Rails, brackets or clips can be reported.

In a fifth embodiment of the invention (see Figure 7), an element (28) comprises three non-shifted boards (29) and four down-planks (31). Notches or rabbets (32) have been formed at the crossing zone between the non-shifted planks (29) and four planks offset downwards (31). These rabbets (32) reduce the space (33) between the boards not shifted (29) and between the boards offset downward (31). In a similar manner to the first embodiment (1), a plate (7) is mounted on the inner edge (8) of the offset planks (31) at the edge of the beam (2). For each beam (2), a localized inner blade (34) is fixed on the inner edge (11) of non-shifted boards (29). The width of this inner blade (34) is substantially equal to the width of the beam (2), its edge arriving roughly to the right of the offset board (31) located at the edge. The blade (34) has its axis substantially parallel to the axis (L) of the boards (3) of these beams (2). This gives a beam (2) in f π. The splitter panel (9) is placed directly on the inner blades

(34).

In a sixth embodiment of the invention (see Figure 8), an element (36) similarly resumes the element (23) of the fourth embodiment, with the beams (2) comprising two non-shifted boards ( 6), three offset plates (4) and the plate (24) suspended on the outer edge of the additional offset board (27). An additional plate (37) is placed on the inner edges of the offset planks (4 and 27) bordering the beams (2).

A concrete layer (38) is cast on the plates (29) and on the entire element (36), so as to cover the beams (2) at the level of the non-shifted boards (6). The concrete (38) forms the secondary structure and reinforces the compressed upper zone. A splitter panel (9) is placed on the concrete (38) and finishes the finish. Concrete (38) is adapted to the need for performance. The choice is one high-performance concrete, light-weight concrete with wood or synthetic aggregates or other traditional concrete.

In a seventh embodiment of the invention (see Figure 9), an element (39) is substantially similar to the element (36) of the fifth embodiment. The concrete (38) is connected to the wood by means of a transverse connector (41), for example making substantially the same width as the beam (2). The splitter panel (9) is placed on the concrete (38). Finally, an additional layer of finishing or soil treatment (42) is provided on the distribution panel (9).

In an eighth embodiment of the invention (see Figure 10), an element (43) with beams (2) has four non-shifted boards (44) and five shifted boards (46). A concrete blade or localized layer (47) is cast on the inner edge of the non-shifted boards (44). This localized layer (47) enters the three spaces delimited by the inner edge of the offset planks (46) and the non-staggered planks (44). The localized layer (47) stops substantially in the middle of the edge of the non-shifted board (44) bordering the beam (2).

A plate (48) is then mounted on this inner edge of the non-shifted board (44) at the edge. The plate (48) serves as formwork for a yoke (49), recumbed on the localized layer (47) and between the beams (2), forming a continuity. This yoke (49) may or may not include an armature (51). A second ceiling can be freely arranged to box the area between two beams (2) and hide the technical facilities.

The finishing layer may remain the concrete screed (49), for example for a tiled finish, or to integrate a floor heating system. It should be noted that this yoke (49) is then a part of the secondary structure of the floor. The concrete (49) does not enhance the bearing capacity of the base beam (2) because the concrete (49) is not connected to the beam (2). It is indeed floating on the secondary panel, consisting of the plates (48).

In a ninth embodiment of the invention (see Figure 11), an element (52) comprises the same beams (2) as those of the eighth embodiment (43). Localized concrete layers (47) are cast on the edge of the non-shifted planks (44). This localized layer (47) enters the three spaces, left by the offset planks (46), between the non-shifted planks (44). The localized layer (46) stops substantially at the edge of the edge of the non-shifted board (44) in edge of the beam (2). A continuous lower panel (53) is fixed on the outer edge of the offset planks (46). This lower panel (53) completely covers and hides the beams (2).

A secondary structure made of continuous squares (48) is mounted on the beams (2). These squares (54), of which an acoustic resilient has been placed under their support on the beam (2), then receive a panel (9) or a traditional floor, or solutions known in the current art. This solution may be suitable in some industrial areas, to save the ceiling panel. The space between the two carrier beams (2) is no longer boxed. In a tenth embodiment of the invention (see Figure 12), an element

(56) has beams (2) with three non-shifted boards (29) and four shifted boards (31), as in the fifth embodiment (28). The non-shifted planks (29) have notches (32) at the crossing zone to allow their adjustment with the offset planks (31) which enclose them. As in the first embodiment (1), a plate (7) is mounted on the inner edge (8) of the offset planks (52) at the edge of the beam (2). For each beam (2), a blade (34) is fixed on the inner edge (11) of non-shifted boards (29). The width of this blade (34) is substantially equal to the width of the beam (2), its edge arriving roughly to the right of the offset board (31) edge. A layer of concrete (57) is cast on the plates (7) and on the blades (34), so as to cover the beams (2) and a part of the space established between them. An acoustic film (58) is placed on the concrete (57) and a linoleum (61) or equivalent, or other materials, finishes the finish.

In an eleventh embodiment of the invention (see Figure 13), an element (62) has beams (2) with four non-shifted boards (6) and five shifted boards (4), as in the eighth (43) and ninth embodiments (52). A secondary structure comprises, respectively from the inner edge of the non-shifted planks (6), a KERTO S panel (63), for example 27 mm thick, an acoustic resilient (64), for example 15 mm thick. thickness and an upper concrete screed (66), for example 50 mm thick.

To ensure continuity between two beams (2), connecting pieces (67) have been provided. For fixing the connecting pieces (67), the visible face of the two offset face-to-face boards (4) of two adjacent beams (2) has notches. These connecting pieces (67) comprise an alternation of offset planks (68) and spacers also offset (69). The inner edges of the staggered boards (68) and offset struts (69) are all at the same level. The outer edges of the staggered boards (68) are all at the same level and the outer edges of the staggered struts (69) are all at the same level, but different from the outer edges of the staggered boards (68).

Only the position of the outer edges of the offset planks (68) and outer edges of the staggered spacers (69) varies with the height. Only the width and thus the apparent height of the offset planks (68), with respect to the width and thus the apparent height of the shifted spacers (69), varies alternately. With these connecting pieces (67), the crenellated continuity of the outer edges of the offset planks (4) and the non-staggered planks (6) constituting the beams (2) is ensured.

In a twelfth embodiment of the invention (see Figure 14), an element (71) has beams (2) with four non-shifted boards (6) and five shifted boards (4), as in the eighth (43) , ninth (52) and eleventh embodiments (62). A secondary structure comprises, respectively from the inner edge of the non-shifted planks (6), an OSB panel (63), for example 10 mm thick, an acoustic resilient (64), for example 15 mm thick and an upper concrete screed (66), for example 60 mm thick. To ensure continuity between two beams (2), connecting pieces (72) have been provided. These connecting pieces (72) comprise an alternation of offset planks (73). These offset boards (73) are placed at different heights, so as to form a staircase. The inner and outer edges of the offset planks (73) are not all at the same level, but are regularly offset perpendicularly to the plane (P). The offset planks (73) of the connecting piece (72) will touch the wooden panel (63) of the secondary structure.

These offset planks (73) give the connecting piece (72) a crenellated appearance in steps. To accentuate the stair step appearance, the offset planks (4) constituting the beams have different widths. A sinusoid is thus apparent with the offset planks (4) of the beams (2) and the offset planks (73) of the connecting pieces (72).

Referring to Figure 15, a first arrangement (74) is formed from a plurality of planar members. This first arrangement (74) is more elaborate, no longer with base beams parallel to each other, but with a grid of beams (76) developed in the XY plane.

A primary wood beam (77) receives other secondary beams (78), for example also similar to the beams (2) of the invention, and tertiary (79). Finally, the complementary structures of floor and ceiling come back in finish, but with plates (81) having much more diverse geometric shapes, triangles, diamonds and other quadrilaterals. This solution makes it possible to develop a superb ceiling in the lower volume.

Referring to Figure 16, a second arrangement (82) is formed from a plurality of wooden beam planar members (2). It is a visible frame with convertible roof. The same finish is found with a secondary ceiling panel (83) and a panel or upper secondary slats, serving as a sub-roof

(not shown)

In the case of this framework, the planar elements mounted in three dimensions have become a farm, with the separate beams (2) with offset planks constituting the rafters and beams serving as pulling (84) to strengthen the farm in the shape of A.

Referring to Figure 17, a third arrangement (86) is used as an anti-noise screen. A planar member (87) substantially resumes the eighth (43), ninth (52), eleventh (62) and twelfth embodiments (71) with four non-shifted boards and five shifted boards. The plane element (87) is installed vertically and is fixed to a support (88), for example a wall. The boards (3) are thus oriented towards the source area (S), from which the sound waves (O) originate in the direction of the front of the arrangement (86).

It follows from the foregoing that the building element according to the invention has multiple advantages, and in particular: an integration of the physical needs of the building, for example, the lighting that can be incorporated in the ceiling box, the thermal insulation can fill all or part of the box, acoustic insulation ground impact noise can also be integrated; - a high resistance to bending by association of offset boards and a secondary structure, with a saving of material through the use of panels or concrete and the spacing between the beams constituting it; and a possible total disassembly of the assembled planks structure when the layout or building is to be removed, allowing reuse of the planks that constitute it or recycling in another industry (formwork, packaging, planks, etc.) .

The present invention is not limited to the embodiments described and illustrated. Many modifications can be made, without departing from the scope defined by the scope of the set of claims.

The embodiments may combine with one another to provide multiple aspects of the finished arrangement. The number of boards constituting the beams is not limiting. The applications are numerous with horizontal or vertical beams, forming elements of partitions or separations, flat or single slope roofs, or two-slope roofs, deck decks, etc.

Claims

1. Construction element, defining a plane (P), comprising a primary structure and a secondary structure substantially parallel to the plane (P), characterized in that the primary structure has at least two distinct beams (2), each having planks of rectangular section (3), parallel to each other, arranged on edge, with their longitudinal axis (L) parallel to the plane (P) of the construction element (1), with one or more boards laterally offset (4) perpendicular to the plane (P), and at least two boards not laterally offset (6); and in that the secondary structure (9) interconnects each of the individual beams (2), at the inner edges of at least two of the laterally non-shifted planks (6).

2. Element according to claim 1, characterized in that it comprises a plate (7) connecting between two adjacent separate beams (2), fixed on the inner edge (8) of two planks face-to-face laterally offset (4), each located at the edge of each of the adjacent separate beams (2).

3. Element according to claim 1 or 2, characterized in that it comprises a plate (19) connecting two adjacent separate beams (2), fixed on the outer edge (21) of the non-facing face-to-face boards. laterally offset (17), each located at the edge of each of the adjacent separate beams (2).

4. Element according to any one of the preceding claims, characterized in that it comprises a plate (24, 53) for connection between two adjacent separate beams (2), fixed on the outer edge (26) of the planks opposite. laterally offset (27, 46), each located at the edge of each of the adjacent separate beams (2).

5. Element according to any one of the preceding claims, characterized in that it comprises a plate (48) connecting two adjacent separate beams (2), fixed on the inner edge of the two planks face-to-face no laterally offset (44), each located at the edge of each of the separate adjacent beams (2).

6. Element according to any one of the preceding claims, characterized in that it comprises a connecting piece (67) between two adjacent adjacent beams (2), fixed on the apparent face of the two plates opposite each other offset laterally (4), formed from an alternation of boards (68) and spacers

(69), laterally offset perpendicular to the plane (P).

7. Element according to any one of the preceding claims, characterized in that it comprises a connecting piece (72) between two adjacent adjacent beams (2), fixed on the visible face of the two non-facing faceplates. laterally offset (44), formed from planks laterally offset (73) perpendicular to the plane (P) and positioned at different stair heights.

8. Element according to any one of the preceding claims, characterized in that the beams (2) comprise an upper blade (34), fixed on the inner edge (11) of the boards not laterally offset (29).

9. Element according to any one of the preceding claims, characterized in that the beams (2) comprise a localized layer of concrete (47), poured by filling the spaces delimited by the boards not laterally offset (44) and the inner edge. laterally offset boards (46).

10. Element according to any one of the preceding claims, characterized in that the beams comprise an alternation of laterally offset planks (4) and boards not laterally offset (6).

11. Element according to any one of the preceding claims, characterized in that the secondary structure is a distribution panel (9) or a series of slats (54), fixed on the inner edge (11) of the boards not offset laterally (6). ) or on the localized layer of concrete (47) or on the upper blade (34).

12. Element according to any one of the preceding claims, characterized in that the secondary structure is a concrete layer (31), cast on the plate (7, 37, 48) and covering the separate beams (2).

13. Element according to any one of the preceding claims, characterized in that it comprises a plurality of connectors (41), inserted in each separate beam (2), perpendicular to the longitudinal axis (L) of the boards (3).

14. Element according to any one of the preceding claims, characterized in that the boards (3) are alternately offset by a distance substantially between 30% and 200%, with respect to the dimension of the crossing zone (5). between said boards (3).

15. Element according to any one of the preceding claims, characterized in that the separate beams (63, 66) are joined to each other, and in that the plates (68) have a substantially triangular shape, rhombic or quadrilateral.

16. An arrangement formed from one or more elements (1, 12, 16, 23, 28, 36, 39, 43, 52, 56) according to one of the preceding claims, characterized in that is a floor, a ceiling (62), a farm (69), a noise barrier (73), forming elements of partitions, walls or partitions, slabs, flat roofs or single slope or two-slope , deck aprons.