FR2832170A1 - ASSEMBLY KNOT, SPATIAL STRUCTURE AND METHOD FOR ASSEMBLING SUCH A STRUCTURE USING SUCH A KNOT - Google Patents

Abstract

This assembly node comprises: - a base plate (31) capable of being assembled with the respective ends (111, 112) of two main chords (1), each end of the chord taking this plate (31) as a yoke and- at least one plate (32, 33) capable of being assembled with the base plate (31) and comprising a first wing (321, 331), extending in a plane (Y-Y ') generally perpendicular to a plane of symmetry (X-X ') of the base plate (31) when the plate (32, 33) is mounted on the base plate (31) and can be assembled with one end (111, 121) of a main chord (1) taking this wing (321, 331) as a yoke. At least a second wing (323, 324, 333) extends in an oblique plane relative to the first wing (321, 331), this second wing being adapted to be assembled with one end (311, 221) of a diagonal chord (2).

Description

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 The invention relates to an assembly node for a spatial structure. The invention also relates to a spatial structure and to a method of assembling such a structure comprising such a node.

 In the field of construction, it is known to make a frame using beams or metal frames which, after assembly on a site, constitute two generally parallel plies formed of members, these plies being braced by beams or diagonal members . This type of structure is known under the name of spatial structure and can be implemented relatively easily by transporting the members before their assembly, which is very practical, while the structure produced is generally hyperstatic and resists efficiently to mechanical stresses, thanks to an optimized distribution of the stresses it undergoes.

 Such a structure is known, for example from FR-A-2,536,775. In this type of structure, it is necessary to provide assembly plates between the members or beams of the unitary elements of the structure, these plates being welded to the associated members. The basic monoblock tetrahedra of the structure must be transported by being already assembled, that is to say relatively bulky, which limits the economic performance of such a structure.

 Assembly nodes for spatial structure are moreover known from FR-A-2 454 010 or from FR-A-2 474 113. These nodes have complex geometries, which increases their cost price . In most cases, they must be pre-assembled in the factory and transported in a relatively bulky manner to the site of installation of a space structure.

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 It is to these drawbacks that the invention more particularly intends to remedy by proposing a new assembly node for a spatial structure which is particularly easy to use, while being economical and allowing excellent distribution of the forces to inside such a structure.

 In this spirit, the invention relates to an assembly node for a spatial structure, this structure comprising main members which extend in at least two generally parallel planes and diagonal members which extend between these planes. This node is characterized in that it comprises: - a base plate capable of being assembled with the respective ends of two main frames, each end of frame taking this plate into a yoke and - at least one plate capable of being assembled with this base plate and comprising a first wing, extending along a plane generally perpendicular to a plane of symmetry of the base plate, when the plate is mounted on this plate, and capable of being assembled with one end of a main frame taking this wing as a fork, and at least a second wing which extends in an oblique plane with respect to the first wing, this second wing being able to be assembled with one end of a diagonal member.

 Thanks to the invention, the main members of the structure can be mounted on the assembly node by taking in screed its parts provided for this purpose, which allows a transmission of forces from these members towards the point d ', without risk of deformation of the node. In addition, the forces transmitted by such a node to the main members, do not risk deforming these members, in particular by buckling.

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 According to advantageous but not compulsory aspects of the invention, this node incorporates one or more of the following characteristics: - The plate comprises a flat back, generally perpendicular to the first wing and forming with the latter at least one dihedral in which the second wing is inscribed, this back being able to come into surface support against the base plate for mounting this plate on this plate. In this case, the node # advantageously comprises two plates, the respective backs of which can take the base plate out of the yoke. It is also possible to provide that the base plate and the back of the plate or plates are provided with orifices for the passage of reversible assembly members of the plate or plates on the base plate. These reversible assembly members can be constituted by bolts. Advantageously, the second wing extends overall in a bisector plane of the dihedral formed by the first wing and by the aforementioned back.

 - The base plate and the wings of the plate or plates are provided with orifices for the passage of reversible assembly members of the members on the node.

 The invention also relates to a spatial structure equipped with nodes as previously described. Such a spatial structure is more economical and easier to assemble than those of the prior art.

 The invention finally relates to a method of assembling a spatial structure comprising nodes as described above and, more specifically, to a method which comprises a step consisting in making assembly nodes by mounting at least one plate provided with wings for fixing the ends of main and diagonal members on a base plate capable of being taken in a yoke by the ends of main members.

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 This process can be easily implemented on the site of installation of the structure, the nodes can be transported in spare parts to this site.

 According to a first advantageous aspect of the invention, the type of plate to be mounted on the base plate is selected according to the expected position of the node in the spatial structure.

 According to another advantageous aspect of the invention, the mounting of the plate or plates on the base plate is carried out by bolting, that is to say reversibly.

 The invention will be better understood and other advantages thereof will appear more clearly in the light of the following description of an embodiment of a spatial structure according to the invention equipped with nodes according to the invention, given solely by way of example and made with reference to the accompanying drawings in which: - Figure 1 is a perspective view of a spatial structure according to the invention; - Figure 2 is a partial side view of the structure of Figure 1 supported by a pole; - Figure 3 is an exploded perspective view of an assembly node used in the structure of Figures 1 and 2 and the ends of associated members; - Figure 4 is a perspective view of a plate used in the node of Figure 3; - Figure 5 is a view similar to Figure 4 for a second plate that can be used in a node of the type of that of Figure 3 and - Figure 6 is a perspective view of the node of Figure 3 used in the structure of Figures 1 and 2.

 The structure S shown in Figures 1 and 2 is formed by assembling beams or members of two

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 kinds. Main members 1 extend in two horizontal planes P1 and P2 in FIG. 2 and constitute the upper and lower limits of the structure S. Diagonal members 2 extend between the main members 1 by joining the planes P1 and P2.

 The members 1 are formed by assembling two angles 11, 12 in the shape of an L or a C, two wings of which are joined together. Similarly, the diagonal members 2 are formed from angle iron 21 and 22 assembled together and two wings of which are joined.

 The angles 21 and 22 may have smaller transverse dimensions than the angles 11 and 12.

 The members 1 and 2 are assembled by means of nodes # 3 on which they are fixed by bolts 4.

 As can be seen more particularly from FIGS. 3 to 6, a node # 3 comprises a generally flat base plate 31 and provided with holes 311 for passing bolts 4 for fixing angles 11 and 12 intended to constitute main members 1. To do this, the ends 111 and 121 of the angles 11 and 12 are provided with holes 112 and 122 for passage of the screws 41 belonging to the bolts 4 and intended to cooperate with nuts 42 also belonging to these bolts.

 There are 312 the parts of the plate 31 in which the holes 311 are formed. These parts 312 are intended to be taken in a yoke by the ends 111 and 121 of the angles 11 and 12, so that the forces exerted by the members 1 parallel to the plate 31 on the node # 3, or by the node # 3 on these members 1, are aligned, with good precision, with a plane P31 of symmetry of the plate 31. We denote XX 'an axis central of the members 1 bolted to this plate, this axis being included in the plane P31.

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 The plate 31 is also provided with four holes 313 allowing the passage of bolts 5 for fixing two plates 32 and 33 intended to take the central part 314 of the plate 31 defined in clevis between the holes 313. For the clarity of the drawing, the bolts 5 are shown only by their center lines in Figure 3.

 The plate 32 is more particularly visible in FIG. 4. It comprises a first wing 321 which is plane and which has for plane of symmetry a plane P321 generally perpendicular to the plane P31 when the plate 32 is mounted on the plate 31. The wing 321 is provided with a hole 3211 for the passage of bolts 4 for fixing the ends 111 and 121 of angles 11, 12 belonging to main members 1 extending along an axis Y-Y ', generally perpendicular to the axis X-X' . The Y-Y 'axis is included in the P321 plane.

 As is apparent from FIGS. 3 and 6, the angles 11 and 12 are not necessarily of L-section. They can have a C-section, as shown for angles 11 and 12 constituting the main members 1 mounted on the plates 32 and 33 along the axis Y-Y '.

 The plate 32 also includes a back 322 generally perpendicular to the wing 321 and extending on either side of the latter. This back 322 is provided with four holes 3221 intended to be aligned with the holes 313 of the plate 31, for the passage of the bolts 5.

 The wing 321 forms, with each half of the back 322, a dihedral according to the bisector plane P323 of which is disposed a secondary wing 323. Another secondary wing 324 is disposed symmetrically with the wing 323 relative to the plane P321. This other wing 324 is centered on a bisector plane of a dihedral defined between the wing 321 and the part shown on the left in FIG. 4 of the back 322. Each

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 wings 323 and 324 is provided with holes 3231, respectively 3241, for passage of bolts 6 making it possible to mount ends 211 and 221 of angles 21 and 22 together forming a diagonal frame 2 and provided with holes 212 and 222 for passage of bolts 6 .

 The ends 211 and 221 of the angles 21 and 22 respectively take the wings 323 and 324 in screed.

 The parts 321 to 324 of the plate 32 are assembled by a weld bead 325.

 The holes 32,31 provided on the wing 323 are aligned in the direction desired for the diagonal member 2 with which they must cooperate.

 In practice, the diagonal members are oriented with an angle a equal to approximately 45 relative to the basic horizontal plane P2 of the structure S. This angle can vary between approximately 30 and approximately 60.

 The plate 33 is identical to the plate 32 and also includes a first wing 331 intended to be taken in a yoke by angles 11 and 12 constituting a main frame disposed in the direction Y-Y '. The plate 33 also includes a back 332 intended to bear against the plate 31. The plate 33 is also provided with two secondary wings, only one of which is visible in FIG. 3, with the reference 333.

 As shown only in FIG. 3 for the member to be mounted on the wing 333, a diagonal member 2 'can also be formed by a tube 21' whose end 211 'is flattened and provided with holes 212' for passage of bolts, which also allows assembly with a secondary wing of plate 32 or plate 33.

 As can be seen more particularly from FIG. 5, it is possible to adapt a node 3 according to the invention when it is to be used in a specific configuration, for example at the level of the support zone of the

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 structure S on a pole P. In this case, a single plate 32 'is mounted on a base plate of the type of plate 31, this plate 32' being provided with a first wing 321 'perpendicular to a back 322' and secondary wings 323 ′ and 324 ′ comprising two series of holes 3231 ′, 3232 ′, 3241 ′ and 3242 ′ making it possible to arrange, according to plane P2, horizontal members 1 ′ oriented at about 45, in top view, with respect to the other horizontal members constituting the lower ply of the structure S.

 Whatever the plates used, the node # 3 can be assembled on the site of installation of the structure S, its various constituent elements, namely base plates 31 and plates 32, 32 ′ and / or 33, being easily transported on this site, at the same time as the angles or tubes intended to constitute the principal and diagonal members of the structure S. Depending on its location in the structure S, each node # 3 can be formed using one or two plates of the type shown in Figure 4 or of the type shown in Figure 5.

 The present invention makes it possible to benefit from the advantages linked to the use of a spatial, hyperstatic structure, in particular the reduction in the number of support points of such a structure used in framework, hence a better use of the covered ground. and an economy on the foundations. Such a spatial structure makes it possible to integrate ventilation and / or heating ducts, as well as projectors or lighting devices, while its resistance to fire is excellent due to its high degree of hyperstaticity. The diagonal or main members can be made by means of angle iron with L profile, equal or unequal, or with C profile, or even with hollow tubes whose ends are

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 adapted to screed at least certain parts of the nodes with which they are associated, for example by means of spacers. The choice of hollow profiles increases the surface weight of the structure but also the rigidity in the framing and bracing.

 Cover or floor tubs can rest directly on the structure without the need to add another profile or support since the sheets formed by the main members are flat.

 The present invention makes it possible in particular to reduce the surface mass of a spatial structure compared to known devices. Indeed, the standard elements constituting the members and the nodes can be optimized as regards their respective thicknesses, because they work globally symmetrically with respect to their respective median planes.

Claims (10)

1. Assembly node for spatial structure (S), said structure comprising main members (1, 1 ') extending in at least two planes (P1, P2) generally parallel and diagonal members (2, 2 ') extending between said planes, characterized in that said node # comprises: - a base plate (31) capable of being assembled with the respective ends (111,121) of two main members (1), each member end taking up said plate and - at least one plate (32, 32 ', 33) capable of being assembled with said base plate and comprising a first wing (321, 321', 331), extending along a plane (P321 ) generally perpendicular to a plane of symmetry (P31) of said base plate, when said plate is mounted on said plate, and capable of being assembled with one end (111,121) of a main frame (1) taking this wing as a yoke , and at least a second wing (323, 324, 323 ', 324', 333) extending along a plane (P323) oblique to said first wing (321, 321 ', 331), said second wing being capable of being assembled with one end (211, 211', 221) of a diagonal member (2, 2 ') .  2. Assembly node according to claim 1, characterized in that said plate (32, 32 ', 33) comprises a flat back (322, 322', 332) generally perpendicular to said wing (321, 321 ', 331) and forming with it at least one dihedral in which is inscribed said second wing (323, 324, 323 ', 324', 333), said back being able to come into surface support against said base plate (31) for mounting said plate on said plate. <Desc / Clms Page number 11>  3. N # ud according to claim 2, characterized in that it comprises two plates (32,33) whose respective backs (322,332) are able to take in screed said base plate (31).  4. N # node according to one of claims 2 or 3, characterized in that said base plate (31) and said back (322, 322 ', 332) of said one or more plates (32, 32', 33) are provided with orifices (3221,313) for passage of members (5) for reversible assembly of said one or more plates on said base plate.  5. N # node according to one of claims 2 to 4, characterized in that said second wing (323, 323 ', 324, 324') extends generally in a bisector plane (P323) of the dihedron formed by said first wing (321) and said back (322).  6. N # node according to one of the preceding claims, characterized in that said base plate (31) and said wings (321,323, 324, 321 ', 322', 324 ', 331,333) of said one or more plates (32 , 32 ', 33) are provided with orifices (3211,3231, 3241, 3231', 3232 ', 3241', 3242 ') for the passage of members (4,6) for the reversible assembly of said members (1, 2 ) on said node (3).  7. Spatial structure (S) comprising members, characterized in that it comprises at least one node (3) according to one of the preceding claims.  8. Method of assembling a spatial structure (S) comprising main members (1, 1 ') extending in at least two planes (P1, P2) generally parallel and diagonal members (2, 2') s 'extending between said planes, characterized in that it comprises a step consisting in producing, assembly nodes (3) by mounting at least one plate (32, 32', 33) provided with wings (321,323, 324, 321 ', 322', 323 ', 331,333) for fixing ends (111, 112,211, 211', 221) of members <Desc / Clms Page number 12>  main (1) and diagonal (2) on a base plate (31) able to be taken in a yoke by ends (111, 121) of main members (1).  9. Method according to claim 8, characterized in that it consists in selecting the type of plate (32, 32 ', 33) to be mounted on said base plate (31) according to the expected position of said node # ( 3) in said structure (S).  10. Method according to one of claims 8 or 9, characterized in that the mounting of said one or more plates (32, 32 ', 33) on said base plate (31) is carried out by bolting (5).