FR2564507A1 - Upright for a beam having a hollowed-out web, beams and buildings including such uprights - Google Patents

Abstract

The uprights consist of plane, substantially solid elements 2 of isoceles-trapezium shape. The beam webs 1 are formed from uprights whose large bases 3 are fixed in mutual alignment to one of the members 4. Their small bases 5, facing a same side with respect to the large bases 3, are extended by substantially parallelepipedal end bodies 6 which are fixed into the other member 7.

Description

 The invention relates to an upright for hollow core beam as well as beams and structures comprising such uprights, said upright being fixed between frames to constitute a beam or a section of beam, said beams or sections of beam being assembled to constitute a prestressed structure.

 A beam, whether simple or boxed, comprises at least one core which is fixed between two members, an upper and a lower. Depending on the intended application, the beams support the loads on their upper or lower members.

The members of at least two beams are optionally connected by the structure formed, for example, of a decking or a concrete slab. The beams, and therefore their webs, are calculated based on the distance between the support points and the load to be supported.

Their mass represents a significant part of the weight of the structure, it is thus, for example that for a concrete bridge deck, the Emes represent 30 to 40 ss of the self weight of the deck. The geometric yield of the section, which is 1 for an iddale section without a core, only reaches 0.6 for a tubular section with solid Smes.

Despite this drawback, the very good resistance of concrete to atmospheric agents has been a determining factor in its widespread use in the total or partial construction of bridges or load-bearing structures, together with the use of longitudinal prestressing by means of internal or external reinforcements. to concrete. This latter type of reinforcement has been widely developed in the field of engineering structures as a result of the reduction in friction of the reinforcements, the elimination of the space requirement of the sheaths inside the cross section of the structure and the maintenance of the thickness. resistant of the souls, while allowing the replacement of the reinforcements. But its layout requires the implementation of bosses, ribs or spacers, ensuring the deflection or anchoring of the reinforcements.
These elements projecting from the current cross section weigh down the structure and their execution, often difficult, increases its grip.

 In order to reduce the longitudinal prestressing, we sought to reduce the self-weight of the structure, in particular by limiting the importance of the ties in the cross section. For this purpose, we tried different solutions, some of which, directly transposed from metal constructions, consist to make triangular Bmes in concrete or metal, or a spatial triangulation connecting the upper and lower chords.

 The use of triangulated checkers requires for areas previously covered by beams with solid areas numerous elements and assemblies (knots, diagonals, bracing, etc ...) which limit a little interest of triangulated fumes. The invention also aims at making beams or sections of hollow beams with hollow cores having the advantages of the beam with planar triangulated core while having better resistance and facilitating the layout of the external prestressing. a section of beam is made up of planar elements, forming uprights, substantially full, in the form of an isosceles trapezium whose large bases are fixed in alignment with one another to one of the members and whose small bases , directed on the same side with respect to the large bases, are extended by substantially parallelepipedic end bodies which are fixed in the other member.

 The explanations and figures given below by way of example will make it possible to understand how the invention can be implemented.

 FIG. 1A is an elevation view of a beam section comprising uprights, according to the invention, directed downwards.

Figure 1B is a sectional view along
B of Figure lA.

 Figure 2 is an elevational view of a beam section in which the uprights are directed upwards.

 FIGS. 3A and 3B are views in elevation and in section of an exemplary embodiment with metal uprights.

 Figure 4 is a cross-sectional view of a box pore made with uprights according to the invention.

 Figures 5 and 6 schematically show a cross section of a structure comprising mes, the uprights of which are inclined relative to the longitudinal plane of symmetry.

 FIG. 7 is an embodiment of a beam seen in section in which the uprights are assembled by one of their beams.

FIGS. 8A, 13, C represent a view in elevation in section along BB and along CC of FIG. 8A a portion of the structure provided with continuous external prestressing flanges passing through the uprights 0
FIGS. 9A, 3, C show a view in elevation, in section along BB and along CC of FIG. 9A, a portion of the structure provided with shooting external preload targets with minimum deviation.

 Figures 10A, 13; 11A, B; 12; 13A, 3 show in elevation and in longitudinal section a portion of the structure on the uprights of which are preload targets or shrouds.

 The section of beam, shown in FIGS. 1A and 1S, comprises a Qme 1, made up of planar elements 22 forming uprights, substantially solid, in the form of an isosceles trapezium whose large bases 3 are fixed in alignment with one another. to one of the members 4. The small bases 5 directed from one mtme cated in relation to the large bases, are extended by an end body 6 substantially parallelepiped which is fixed in the other member 7. The amount extends between the upper and lower members of the beam.

 At least a part of wool is formed by amounts arranged in the same direction (which will be chosen arbitrarily from the large base to the small base).

 Depending on whether the large bases are fixed to the upper member or to the lower member, the arrangement shown in FIG. 1A or in FIG. 2 is obtained. In the eas of FIG. 1A, the large bases 3 of the uprights ensure continuous embedding of the upper chord 4 under the effect of operating loads (road or rail loads). In the case of FIG. 2, the upper member rests on the end parts 6 and the behavior of the beam is similar to that of a triangulated core structure. This arrangement is particularly suitable for the installation of aprons by longitudinal displacement (pushing) of the large base 3 of the uprights 2 ensuring the diffusion of the concentrated forces transmitted by the sliding devices during displacement.

 According to an embodiment not shown, the cores have at least one portion in which the direction of the uprights is opposite to that of the uprights of the neighboring portions.

The hollowed-out webs of the beams obtained from trapezoidal uprights have the advantage of having a mechanical behavior very similar to planar triangulated webs. The flexural isostats, which must bypass the recesses, substantially follow the outline of the fictitious lattice inscribed inside the trapezoidal uprights and represented in FIGS. 1A and 2 in broken lines. It should be noted that the isostats are distributed along the sides of an isosceles triangle inscribed in the trapezoidal uprights and the apex of which is located in the body of the parallelepipedal end of the upright ensuring the connection with the frame.
In the previous examples, the trapezoidal uprights were made of concrete, but according to the embodiment shown in Figures 3A and 3S, the upright is a plate of metal or a composite material such as a honeycomb structure. 'end 6 forms a heel for example of concrete, which is secured to one of the members (for example 7), while the large base 4 is secured to the other member (for example 4).

 According to the structure to be produced, the cores according to the invention are vertical such that in the cross section shown in FIG. 4, they can also be inclined on the vertical and make acute angles (FIG. 5) or with the upper chord. obtuse angles (Figure 6). This inclination relative to the longitudinal plane of symmetry of the structure can also be obtained when the member (s) have a double cant. The uprights can then be fixed substantially perpendicular to the tangents at the points of attachment to the members.

 According to another embodiment, the uprights of two neighboring EMS are assembled so as to constitute transverse dihedrons or "doublets" (FIG. 7).

 the uprights can be concreted in place or prefabricated. their concreting is made easy by their trapezoidal shape which facilitates the placement of concrete in the formwork. If the uprights are prefabricated, they are generally executed flat, like slabs and their connection is made by the upper and lower slabs.

 The uprights can also form sections of box girder (as shown in the section in Figure 4).

the segment or segment is limited to the length of an upright, between the transverse planes A and
B (Figure 1) passing through the ends of the large bases, or comprises several uprights, the number being limited by the power of the handling means available or by the economic dimension of the formwork.

 In the case of metal or composite uprights, these are directly manufactured in the factory and are provided with connectors which ensure the connection of their large bases with a frame and their small bases with the end bodies.

 According to a preferred embodiment, the uprights are provided at least in the end bodies 6 with at least one passage tube for the target of the temporary assembly or the prestressing cable 9.

To this end, the end bodies 6 may have lateral thickening 10 (FIGS. 8C, 9C) which has the purpose of approximately compensating for the volume of the passage tubes. Optionally, the end body has a height greater than that of the lower member and has a heel 11 facilitating the coating of the reinforcement and serving as a primer for the thickening of the lower member 7.

 According to another embodiment, the transverse rib 12 is hooked on the part of the end body located above the memb-r-ur7 (Figure 8B).

 the transverse ribs possibly carry tubes for passing the prestressing targets.

 FIGS. 8 A, B, C and 9 A, B, C show two examples of the passage of prestressing targets in a structure produced using uprights according to the invention. In FIGS. 8A, 13, C the external preloading target 9 passes through a passage tube 8 of the end body of a trapezoidal upright.

 This tube has the shape of a left curve allowing the deviation of the target both in the vertical plane and the horizontal plane. The cable is then deflected in the horizontal plane by passing through a tube 13, curved in a plane, provided in a transverse rib.

 In FIGS. 9A, BSC, one of the uprights comprises a passage tube 8 in the shape of a left curve and the following upright or uprights of longitudinal straight tubes 14 through which pass external, horizontal prestressing cables 9 having a minimum deviation.

 FIGS. 10 A, B show the anchoring of a target end 9 of lower prestressing in a straight passage tube t4 inclined in the horizontal plane on the longitudinal axis2l of the uprights.

 The target 9 is deflected in a transverse nermlre 12 which it crosses in a passage tube as in the example of FIG. SA.

 FIGS. 11A and B show a form of anchoring of preload targets for beams, the cables being outside the concrete and arranged in a fan shape from a support.

 The passage tubes 15 are in this case rectilinear and provided in the trapezoidal portion of the upright. the target anchors 16 are supported perpendicularly on the bottom of a notch 17 into which the cabal passage tube opens. This arrangement makes it possible to uniformly distribute the compression forces exerted by the target.

FIG. 12 represents a portion of the structure in which an anchoring of prestressing cables outside the concrete is provided, arranged above the upper chord of the deck or shrouds,
As in the previous example, notches 17 are provided on the edge of the uprights.

 Figures 13A and B show a portion of the work in which one of the uprights carries near the large bases of the openings 18 allowing, thanks to the cable passage tubes provided in the thickness, to make an anchoring of horizontal prestressing cables arranged horizontaur in the support area of the deck.

 .The examples described above are made with beams whose beams are directed downwards, the transposition to beams.

whose amounts of the tmes are directed upwards is easily conceivable and does not require further development.

the advantages presented by the trapezoidal uprights c-constituting the hollow Bmes compared to those constituting the lattice or solid webs are numerous. Among these we can cite:
- the economy of concrete for the manufacture of boards (compared to a full Bme); ;
- the economy of prestressing by an improved geometric yield of the section and by a reduction in weight
- the easy manufacture of the tunes, the trapezoidal uprights of low weight being able to be prefabricated apart, for example like slabs, or concreting in place to form the enzymes
- The longitudinal prestressing of the apron exclusively by targets external to the concrete and replaceable, without the use of bosses or spacers of cores, the deflection and anchoring of the cables being ensured by the trapezoidal uprights.

Claims (9)

REVEEDIChEIONS  1. Upright for hollow beam, said upright being fixed between the members to constitute a beam or a section of beam, characterized in that it consists of a planar element (2) in the shape of an isosceles trapezium, the small base (5) is extended by an end body (6) approximately parallelepiped.  2. Upright according to claim 1, characterized in that it is made at least partially of concrete.  3. Upright according to claim 1, characterized in that in its thickness, passage tubes (8,14,15) for targets or shrouds (9).  4. Upright according to one of claims 1 to 3, characterized in that it comprises on the edge of the non-parallel sides of the element (2) - and at one end of the passage tube (15) a notch (17 ) whose bottom is intended to retain a cable anchor (16).  5. Amount according to one of the preceding claims, characterized in that the end body (6) carries in an approximately longitudinal direction passage tubes (15) of cables or shrouds.  6. Beam with hollow core using uprights according to one of the preceding claims, characterized in that the core is made up at least in part of successive trapezoidal uprights whose large bases (3) are fixed in alignment one of wall to one of the frames (4 or 7) and whose end bodies (6) located on the same side relative to the large bases are fixed to the other ~ frame (7 or 4).  7. Beam according to claim 6, characterized in that the friend consists at least in part of successive uprights directed in the opposite direction to that of the uprights of the other party, the direction of the uprights being defined from the large base towards the small base.  8. Work formed by at least one beam in accordance with claim 6 or 7 comprising prestressing targets, characterized in that said targets pass through curved passage tubes (8), provided in at least one end body, an upright, said tube deflecting the target in front of the neighboring uprights.  9. A work comprising uprights according to one of claims 6,7,8, characterized in that prestressing cables pass through straight passage tubes (14) and aligned end bodies (6) of successive uprights.