FR3009262A1 - STRUCTURE IN COMPOSITE MATERIALS FOR WAGON CHASSIS - Google Patents

Abstract

The subject of the invention is a structure made of composite materials for a vehicle chassis, said structure being configured to receive a train running at each of its ends. This structure comprises at least one central beam (31) which comprises a median box (314) having a central part (311) and two ends (312, 313) with the reinforced structure, the central part itself comprises a reinforced part increasing the resistance of the beam (11) to the bending forces imposed by the load carried. The median box (314) is reinforced by two lateral boxes (315, 316) extending over the entire length of the median box (314), assembled to said median box, whose upper faces form with the upper face of the median box the upper face of the beam. The structure also includes a floor (32) that covers the upper faces of the middle box (314) and side boxes (315, 316). The elements constituting the structure have advantageously simple shapes, easy to make from composite materials and easy to assemble.

Description

The invention relates to the general field of structures for rolling stock. The invention relates more particularly to a composite beam design for lightening, using composite materials, the structure of a rail transport vehicle (wagon), rail freight transport in particular.

The wagon construction sector, as is the case in all areas of transport, seeks to reduce the mass of structures forming the vehicle in order to increase payload and / or reduce transport costs by controlling both the production costs of the vehicles and their energy consumption. To date the wagons are exclusively formed of metal structures, usually steel and sometimes aluminum. However, it is natural for transport to consider lighter realizations, particularly using composite materials. But it is also known that one can not replace, by simple substitution of material, a metal structure for a structure of identical shape of composite material. It is usually necessary to completely redesign structures to exploit all the technical characteristics and properties specific to composite materials. The need to redesign these structures in the context of the use of composite materials owes in particular to the particularities described hereinafter. A first feature to consider is the anisotropic nature of the composite materials, character which results that their properties, their mechanical properties in particular, are not identical in all directions, because of the presence of reinforcing fibers component material. Such a feature requires defining a material architecture adapted to each application. Another particularity to be considered is the variety of manufacturing processes used (molding, vacuum infusion, RTM (Resin Transfer Molding), draping, ....) as well as assembly techniques, used to assemble elements made of materials. composites, are generally specific to these materials. Contrary to what happens with metals, it is indeed hardly possible, for example, to weld thermosetting composite materials, but it is quite appropriate to assemble such materials by gluing, which is exactly the same. opposite of what is possible to achieve with metals. Yet another particularity lies in the specificities of the different variants of composite materials available, in particular as regards the nature of the fibers used, mineral fibers (glass fibers, carbon fibers, etc.) or organic fibers, which are gives the corresponding composites properties, behaviors, as well as different costs. Thus, composite materials based on glass fibers are the least expensive, while the carbon fiber composite 20 appear the most expensive. Because of these features, the use of composite material structures for producing rolling stock capable of transporting heavy loads, is currently little or not developed, particularly with regard to the manufacture of freight cars in particular. It is recalled here that the composite materials considered are so-called "structural" composite materials which are materials based on long, continuous fibers which represent approximately 50% of the material, the remaining 50% being constituted by a matrix, generally in thermosetting resin, epoxy type (EP), diallylphthalate (DAP), polyester or vinylester for example and, more rarely, thermoplastic resin, polyamide type, PEEK or PEI for example.

An object of the invention is to provide a particular structure of composite material that can be used to manufacture vehicles such as those mentioned above. In particular, an object of the invention is to define a wagon platform structure, whose shape characteristics are optimized to allow its manufacture in composite materials. The ultimate goal here is to significantly reduce the mass of a wagon structure, while optimizing manufacturing costs for robustness performance equal to or greater than the performance of current structures. For this purpose, the subject of the invention is a structure made of composite material, in particular for a chassis for a vehicle for transporting goods or passengers, said structure being configured to receive a running gear or a bogie at each of its ends, said structure comprising at least one central beam forming a plate on which the load of the vehicle rests. According to the invention, said beam 20 comprises: - a median box having a central portion and two ends, said ends having reinforcements for supporting the stresses transmitted to the frame by the hinge elements of the running gear and by the absorption elements shocks, disposed at the ends of the vehicle, the central portion of the median box being configured to have a reinforced portion increasing the resistance of the beam to the bending forces imposed by the load carried; - Two lateral boxes extending over the entire length of the median box, assembled to said median box, and whose upper faces 30 form, with the upper face of the median box, the upper face of the beam. Said lateral caissons are configured so as to reinforce the resistance of the beam to the longitudinal and transverse bending forces imposed on it; - A covering floor forming a skin, configured to cover the upper faces of the median box and side boxes. According to the invention, the various elements constituting the beam are made of composite materials with fiberglass or carbon fiber reinforcements or a mixture of glass fibers and carbon fibers. According to various arrangements which may be considered alone or in combination the structure according to the invention has several complementary features. Thus: According to a particular characteristic, the median box consisting of an upper half-box extending over the entire length of the beam and a lower half-box disposed in central part, the two half-boxes each comprising a bottom and two side walls. The upper half-box and the lower half-box are arranged relative to one another so that the bottom of the upper half-box forms the upper face of the middle box and the bottom of the lower half-box. forms the underside of said box. The bottom of the lower half-box also extends outside thereof towards the ends of the beam. According to another particular characteristic, an intermediate partition of composite material is placed between the upper half-box and the lower half-box, so as to reinforce the rigidity of the median box and the buckling resistance of the side walls of the half-box. upper and side walls of the lower half-box. According to another particular characteristic, the covering floor consists of a plate-shaped main element (61) made of monolithic composite material with fiberglass reinforcement, comprising in its middle part a reinforcement element (62) made of composite material sized to cover the upper face of the median box (314). According to another particular characteristic, the bottom of the upper half-box, the bottom of the lower half-box and a median reinforcement element of the main element of the skin disposed on the upper face of the structure are made of monolithic composite material with reinforcement consisting mainly of unidirectional fibers, said fibers preferably being carbon fibers. According to another particular characteristic, the structure according to the invention further comprises lateral reinforcements made of composite material disposed on either side of the beam and arranged so as to ensure the recovery of the forces applied to the lateral parts of the structure by the load transported. Each reinforcement is secured to a lateral box by one of its ends and the median box by its other end. According to another particular characteristic, the elements forming the beam consist of planar faces of composite material. According to another particular characteristic, the upper half-box comprises a bottom consisting of a plate of monolithic composite material and sandwich-structure side walls consisting of two thin skins made of composite material with fiberglass reinforcement and of one core constituted by an element made of foam of polymer material, or of a material with a honeycomb structure, or of a balsa-type wood. According to another particular feature, the lower half-box comprises a bottom consisting of a monolithic composite material plate 20 and sandwich-structure side walls consisting of two thin skins made of composite material with fiberglass reinforcement and a core constituted by an element made of foam of polymer material, or of a material with a honeycomb structure, or of a balsa-type wood. According to another particular characteristic, the lateral reinforcing elements have a sandwich structure consisting of two thin skins made of composite material with fiberglass reinforcement and a core consisting of a foam element made of a polymeric material or a plastic material. honeycomb structure, or in a balsa type wood. According to another particular characteristic, the various elements of the structure according to the invention comprise flanges arranged to allow the assembly of said elements by gluing and / or bolting and / or riveting, two elements assembled one to the other. another having ledges arranged so as to be placed vis-a-vis at the time of assembly.

The features and advantages of the invention will be better appreciated thanks to the following description, which is based on the appended figures which show: FIGS. 1 and 2 are diagrammatic illustrations showing the basic structure of the chassis according to FIG. invention in side view and in frontal section at the middle portion of the frame. - Figure 3, a schematic side view, in section, of an embodiment of the frame according to the invention; - Figure 4 is a schematic cross-sectional view of the frame of Figure 3, in a plane passing through the central zone of the structure; - Figure 5 is a schematic cross-sectional view of the frame of Figure 3, in a plane passing at one end of the structure; - Figure 6, a schematic cross-sectional view of the tray surmounting the structure of the frame according to the invention, in the embodiment of Figure 3; - Figure 7, a schematic cross-sectional view of the upper half-box constituting the beam of the frame according to the invention, in the same embodiment; - Figure 8 is a schematic cross-sectional view of the lower half-box constituting the beam of the frame according to the invention, in the same embodiment; - Figure 9, a schematic cross-sectional view of a lateral box 30 constituting the beam of the frame according to the invention, in the same embodiment; - Figure 10 is a schematic cross-sectional view of a lateral reinforcing panel that can be integrated with the beam of the frame structure according to the invention; FIG. 11 is a diagrammatic illustration of the various steps of assembling the structure according to the invention.

The schematic figures 1 and 2 are intended to present the basic structure of the frame according to the invention. According to this principle the frame according to the invention mainly comprises an upper plate 11 intended to support the transported load 13, having end reinforcements 111 and 112, and a lower box 12, or reinforcement, located under the central part of the plate 11 intended to give the assembly increased rigidity in the central part, in particular in terms of longitudinal and transverse bending. The end reinforcements have for their main function to ensure the recovery of forces imposed on the structure at the hinge axes 113 and 114 of the chassis with the running gear of the vehicle (bogies), and the recovery of the forces experienced by the vehicle, the wagon, at the level of the connecting pieces, shock absorbers or end buffers, etc. According to the invention, the various structural elements of the frame are made of composite materials. The structure of each of the elements is furthermore defined in such a way that the parts to be subjected to stresses in the plane are constituted by simple webs of composite material, with a monolithic structure, preferably comprising a reinforcement of longitudinally oriented fibers, while the parts of an element to undergo off-plane stresses, twists for example, have a sandwich structure formed of two skins of composite material separated by a spacer element, a core, made of a filling material, preferably the lightest possible, a foam of polymeric material of the type PS, PVC, PU, PET for example, or nida or a low density wood, of balsa type for example ... According to the constraints that must bear the structural element considered , the fibers constituting the reinforcement of the composite material used are either glass fibers or carbon fibers, which are either in the form of unidirectional folds (UD) or in the form of woven folds (fabrics) that are stacked as much as necessary. The structure of each panel, that is to say the choice of folds, their orientation in the material, their stacking is achieved through simulation tools well known to those skilled in the art; knowing that we are always looking for an optimization in terms of mass and cost of production of the piece that we conceive.

The following description shows an embodiment of a wagon chassis built on this type structure. This example is intended to highlight the particular technical features of the invention. The scope of the invention is of course not limited to the scope of this single example. As illustrated in Figures 3 to 5, in this embodiment, the wagon chassis according to the invention consists mainly of a beam 31 which includes the functionalities of the upper plate 11 and the lower box 12 of the structure of principle described above, the beam 31 being covered with a coating plate 32. The coating 32, or skin, is a planar element, of relatively small thickness, made of composite material, the dimensions of which are defined so that it covers the entire surface of the structure (chassis). In a preferred embodiment, the skin 32 is constituted by a first planar element 321 made of fiberglass reinforced composite material having a reinforced middle portion on its underside by a second flat element 322 made of composite material with fiberglass reinforcement. also. In particular embodiments, however, the second element 322 can also be made of carbon fiber reinforced composite material, optionally UD, so as to have in particular a greater mechanical strength (traction / compression and bending in particular). and a lower weight-resistance ratio.

The beam 31 forming the plate has a central portion 311 and two end zones 312 and 313 on which are articulated the running gear of the vehicle, ie the bogies of the car in the present example. From a structural point of view, the central portion 311 and the two ends 312 and 313 of the beam 31 are constituted by a single element, made of composite material, incorporating reinforcing elements 35, 36 at its ends, as 3 and 5. These reinforcement elements, in the form of webs or beams of composite material, are intended in particular to reinforce the zone of connection and articulation with the bogies as well as the transmission of the forces applied to the buffers. In this example of implementation, the beam 31 according to the invention consists of a median box 314 and two side boxes 315, 316 located on either side of the middle box 314, in the longitudinal direction, and 10 assembled to the median box 314. According to the variant embodiment considered the median box 314 can be made in one piece. Nevertheless, for reasons of ease of embodiment in particular, it is preferably made in two parts, an upper half-box 317 extending over the entire length of the wagon 15 and a lower half-box 318 which reinforces the half upper box 317 in the central zone 311 of the beam 31. The upper half-box forms both the central portion 311 and the reinforced ends 312 and 313 of the beam 31. The lower half-box 318, located only in the central part of the wagon has a bottom wall 319 which has the function of reinforcing the bending inertia of the assembly. For this purpose, this wall 319 extends, as illustrated in FIG. 3, beyond the limits of the lower half-box 318 to the end zones 312 and 313 of the upper half-box 317, so as to close said upper half-box and thus participate in the resumption of efforts, printed in particular by the axes of articulation of bogies. The height of each half-box, in particular that of the lower half-box 318, is defined according to the manufacturing choices chosen to meet the mechanical stresses that the structure must bear, especially the weight of the load. The side boxes 315 and 316 are, for their part, are continuous elements along the entire length of the wagon. Located on either side of the upper half-box 317, they constitute with it the upper face of the beam 31 on which the skin 32 rests. They also contribute to the longitudinal and transverse flexural strength of the frame thus formed and participate the resumption of efforts to the right of tampons.

In a particular embodiment, illustrated in FIG. 4, the central part of the beam 31 is moreover laterally reinforced by lateral elements 33 and 34 made of composite material, arranged obliquely and which, according to the variant of embodiment considered, dress this central portion continuously along its entire length and form 2 side reinforcing walls, or, alternatively, constitute localized reinforcements, forming oblique reinforcing bars spaced from each other along the central part of the beam 31. These elements reinforcement 33 and 34 serve for the recovery of transverse bending forces and thus limit any torsion of the structure.

It should be noted that, according to the respective heights of the upper and lower half-boxes, it is possible, in a particular embodiment, to add an intermediate plate to stabilize the median box 314 made from these two half-boxes 317 and 318, this plate or partition, intermediate has the function of preventing buckling of the side walls of the upper and lower half-boxes. Figures 6 to 10 show the morphological and structural characteristics of the various elements described above.

As illustrated in FIG. 6, the panel constituting the skin 32 disposed on the upper face of the structure consists of a main planar element 61 covering by its dimensions the totality of the surface formed by the upper faces of the median box 314 and the lateral caissons 315 and 316 and a median reinforcing element 62, also plane, disposed facing the upper face of the median box 314. According to the embodiment envisaged, the main element 61 may for example be made of composite material with reinforcing fiberglass, as well as the reinforcing element 62. However, in particular embodiments, the second element 62 may also be made of a composite material with carbon fiber reinforcement, possibly UD, so to have greater mechanical strength (traction / compression and bending in particular) and a lower weight-resistance ratio. The illustrations of FIGS. 7 and 8 detail the morphology and the structure of the upper half-box 317 and the lower half-box 318 which constitute the middle box 314. The upper half-box 317 is formed mainly of a bottom 71 formed by a monolithic wall of composite material, and two side walls 72 and 73, these walls extending over the entire length of the median box 10. The monolithic bottom 71 may according to the embodiments envisaged consist of two skins (76, 77) made of composite material with fiberglass reinforcement, the reinforcement mainly consisting of UD layers of glass fibers, or alternatively, for reasons mechanical strength in particular and lower weight-resistance ratio, made of composite material with carbon fiber reinforcement. The two side walls 72 and 73, for their part, have a sandwich structure formed of two skins 76, 77 made of composite material separated by an intermediate element 78, a core made of a filling material, a foam of polymeric material of the same type. PS, PVC, PU, PET for example, or a honeycomb structure material (nida) or a balsa type wood for example. Their sandwich structure allows the side walls to have a better buckling stability. As can be seen from FIGS. 3, 4 and 5, the upper half-casing 317 has a generally parallelepipedal overall shape with an open face, opposite to the bottom-forming face 71. According to a preferred embodiment, the Side walls 72 and 73 each have a flange 74 or 75 extending laterally outwardly of the half-box over the entire length thereof, this flange 30 being used to complete the assembly of the complete frame. The lower half-box 318 is mainly constituted, as the upper half-box of a bottom 81 and two side walls 82 and 83 which border the central part of the middle box 314. As well as the walls 72 and 73 of half upper box, the two side walls 82 and 83 here have a sandwich structure. The bottom 81, which extends, as has been said previously, over the entire length of the structure and which has the function of reinforcing the bending inertia of the whole structure (of the frame), also presents a monolithic structure consisting, according to the embodiments envisaged, of the two skins made of composite material with glass fiber reinforcement, the reinforcement mainly consisting of UD layers made of glass fibers, or alternatively, in particular for reasons of mechanical strength and 10 lower weight-resistance ratio, made of composite material with carbon fiber reinforcement. From a morphological point of view, the lower half-box 318 has a trapezoidal-shaped prism shape whose bases represent the side walls 82 and 83 of the half-box. The front and rear faces 15 of the half-box are constituted by the bottom 81 which extends obliquely forwardly and rearwardly, beyond the lower half-box 318, so as to come gradually in contact upper half-box 317, by its edges 74 and 75, as shown in Figure 3 for example. In a preferred embodiment, illustrated in FIGS. 7 and 8, the side walls 72 and 73 each have a flange 84 or 85 extending laterally outwardly of the half-casing considered over the entire length of the housing. this latter, this flange being used to complete the assembly of the complete frame. Similarly, the side walls 82 and 83 each have a flange 84 or 85 extending laterally outwardly of the half-box over the entire length thereof. The bottom 81 has, on its part extending out of the lower half-box, flat flanges 86 and 87, used to complete the assembly of the complete frame. The flanges 86 and 87 are configured and arranged such that they are placed, at the ends of the structure, facing the flanges 74 and 75 of the side walls of the upper half-box 317. Similarly, the flanges 84 and 85 are themselves configured and arranged such that they are placed, at the central part of the structure, opposite the flanges 74 and 75 of the side walls of the upper half-casing 317. The presence of such flanges advantageously facilitates the assembly of the lower half-box 318 and the upper half-box 317 into a single median box 314. This assembly can for example be made by gluing the flanges, or by riveting or bolting, or by a joint assembly collage-plusrivetage of these same edges. From a morphological point of view, the side boxes 315 and 316 have identical shapes. As illustrated in Figure 9, each box has a vertical inner side wall 91, intended to come into contact with one of the side walls of the upper half-box 317 and an outer side wall, oblique 92 forming an outer upper edge of the frame . The oblique orientation of the outer lateral wall advantageously makes it possible to produce a support without adjustment to assemble the lateral elements 33 and 34. The lateral walls of a lateral box are interconnected by a flat bottom 93 parallel to the plane of the bottom 71 of the upper half-box. From a structural point of view, the walls of lateral caissons are constituted, as the side walls of the upper half-boxes 317 and lower 318 of two skins made of composite material, reinforced with glass fibers, separated by a core made of filling, foam of polymeric material, or material honeycomb structure (nida), or wood, such as balsa. According to a particular embodiment, a filler material may be furthermore integrated in the caissons 315 and 316, a material consisting of either a foam of polymer material, or a honeycomb structure material (nida), or else Balsa type wood for example. This material makes it possible to bind the inner skins 91-92-93 of the lateral boxes 315-316 to one another and to the skin placed on the upper face of the plate 32.

From a structural point of view also, the lateral reinforcement elements of composite material 33 and 34, intended to reinforce the resistance to torsion and bending (longitudinal and transverse) of the frame structure according to the invention are also constituted, as the side walls of the upper half-boxes 317 and lower 318 of two skins made of composite material, reinforced with glass fibers, separated by a core constituted either of foam of polymeric material or of a material having a nest structure bee (nida), or even balsa type wood for example. In a preferred embodiment illustrated in FIG. 10, the body 101 of the reinforcement is extended by flanges 102 and 103 arranged with respect to the body 101 so as to facilitate the assembly of the considered reinforcing element with the external side wall of the corresponding lateral casing 315 or 316 and with the side wall of the lower half-casing 318. This assembly can for example be made by bonding the flanges, or by riveting or bolting, or by a joint collageplus -rivetting of these same edges. As can be seen from FIGS. 6 to 10, the frame structure according to the invention, as described in the foregoing text, has the important advantage of being composed of elements having both a simple morphology and easy to assemble (faces and supports on plane faces), as well as an internal structure easy to realize. These characteristics advantageously make it easier to assemble such a structure, despite the sometimes large dimensions of the latter.

The composite material elements forming the structure according to the invention being simple shaped elements having flat faces, the structure according to the invention can advantageously be constructed in a simple and inexpensive way, the various elements made of composite materials constituting the structure which can be carried out by using simple processes, mainly by draping prepregs and / or dry fibers, combined with a vacuum or RTM polymerization, or by infusion taking into account the large size of the manufactured elements, such as than those used in the realization of wind turbine blades for example.

Furthermore, considering the concept of composite structure according to the invention, the assembly of the various composite elements constituting the frame according to the invention is advantageously simple to achieve insofar as all the connections take place along planar and linear supports provided for this purpose, the assembly can be achieved using tools not very complex, by gluing, or by riveting or bolting, or by a joint assembly collage-plus-riveting different elements to each other for example. FIG. 11 schematically illustrates the method of assembling a chassis structure according to the invention from the constituent elements described above, which method comprises: a first step (step 1) which consists in assembling the half-casings; upper caissons 317 and lower 318 to form the median box 314; a second step (step 2) which consists in assembling the lateral caissons 315 and 316 on the median caisson 314 to constitute the beam 31 forming the plate of the structure, the assembly being carried out at the level of the upper half-casing 317; possibly having integrated in the casings 315-316 a filling material consisting of either a foam of polymeric material, or a honeycomb structure material (nida), or even of balsa type wood by example. - A third step (step 3) of fixing the skin 32 on the upper face of the beam 31 so as to cover the upper faces of the upper half-box 317 and the side boxes 315 and 316; a fourth step (step 4) consisting, where appropriate, in fixing the lateral reinforcing elements 33 and 34 on the beam 31. It should be noted that, in the case where the frame produced actually comprises lateral reinforcing elements, steps 3 and 4 can be switched. Furthermore, according to the embodiments envisaged, steps 1 to 4 may be performed in a different order, for example 2, 3, 1, 4 or 3, 2, 1, 4. It should also be noted that, during the second step, the assembly of the upper half-boxes 317 and lower 318 can be made by interposing between the two half-boxes, at the connection of the flanges 74-75 and 84-85, a intermediate plate, as described above, this plate having the function of reinforcing the rigidity of the assembled beam. According to the invention, the composite beam 31 thus produced integrates at its ends, at the level of the reinforcements, metal elements whose role is, in particular, to interface with the bogies and with the end buffers. The fixing of the metal elements to the composite material structure according to the invention is carried out by appropriate fastening means (bolts and / or rivets), for example by using an appropriate technique of assembly between metal parts and parts made of material composite, such as that described in patent FR 2 948 154 belonging to the applicant. As a result, the complete embodiment of a frame according to the invention also comprises an operation of placing and fixing the interface elements on the beam 31, at the ends of the boxes 315, 316 and 317, an operation which according to the manufacturing method adopted can be carried out on the boxes before assembly or during assembly, after step 2 for example. As can be seen from the preceding description, this invention can be used on all types of railway vehicles intended for the transport of freight (wagons) or passengers. It can also be used to make chassis of road freight vehicles, truck trailers in particular.

Claims (11)

REVENDICATIONS1. Composite material structure, for a vehicle chassis for transporting goods or passengers, said structure being configured to accommodate a train running at each of its ends, characterized in that it comprises at least one central beam (31) forming a plateau on which the load of the vehicle is based, said beam comprising: - a median box (314) having a central part (311) and two ends (312, 313), said ends having reinforcements (35, 36) for supporting the transmitted stresses to the chassis by the articulating elements of the running gear and by the shock absorbing elements, arranged at the ends of the vehicle, the central part of the median box (314) being configured so as to have a reinforced part increasing the resistance of the vehicle; beam (11) at the bending forces imposed by the load carried; - two lateral boxes (315, 316) extending over the entire length of the median box (314), assembled to said median box, whose upper faces form with the upper face of the median box the upper face of the beam, said boxes laterally configured to increase the resistance of the beam to the longitudinal and transverse bending forces imposed on it - a covering floor (32) forming a skin, configured to cover the upper faces of the median box (314) and side boxes (315, 316); The various elements constituting the beam (31) being made of composite materials reinforced with glass fibers or carbon fibers or a mixture of glass fibers and carbon fibers. 2. Structure according to claim 1, characterized in that the median box (314) consists of an upper half-box (317) extending over the entire length of the beam and a lower half-box (318). ) disposed in the central portion (311), the two half-boxes each having a bottom and two side walls, the upper half-box (317) and the lower half-box (318) being arranged relative to each other so that the bottom (71) of the upper half-box (317) forms the upper face of the median box (314) and the bottom (81) of the lower half box forms the underside of said box, the bottom half lower box (319) extending outside thereof towards the ends (312, 313) of the beam. 3. Structure according to claim 2, characterized in that an intermediate partition of composite material is placed between the upper half-box (317) and the lower half-box (318), so as to reinforce the rigidity of the median box ( 314) and the buckling resistance of the side walls (72, 73) of the upper half-box (317) and the side walls (82, 83) of the lower half-box (318). 4. Structure according to any one of claims 1 to 3, characterized in that the covering floor consists of a main element (61) in the form of a plate, a monolithic composite material with fiberglass reinforcement, comprising in its middle part a reinforcing element (62) of composite material sized to cover the upper face of the median box (314). 5. Structure according to any one of the preceding claims, characterized in that, the bottom (71) of the upper half-box (317), the bottom (81) of the lower half-box (318) and an element medial reinforcement (62) of the main element (61) of the skin (32) disposed on the upper face of the structure are made of monolithic reinforced composite material consisting mainly of unidirectional fibers, said fibers being preferentially carbon fibers . 6. Structure according to any one of the preceding claims, characterized in that it further comprises lateral reinforcements (33, 34) of composite material disposed on either side of the beam (31) and arranged to to ensure the recovery of the forces applied to the lateral parts of the structure by the transported load, each reinforcement being secured to a lateral box by one of its ends and the median box by its other end. 7. Structure according to any one of the preceding claims, characterized in that the elements forming the beam (11) consist of flat faces of composite material. 8. Structure according to any one of the preceding claims, characterized in that the upper half-box (317) comprises a bottom (71) plan consisting of a plate of monolithic composite material and two side walls (72, 73). with a sandwich structure consisting of two thin skins (76, 77) made of fiberglass reinforced composite material and a core constituted by an element (78) formed either of polymer material foam or of a structural material honeycomb, or is still balsa type wood. 9. Structure according to any one of the preceding claims, characterized in that the lower half-box (318) comprises a bottom (81) consisting of a monolithic composite material plate and side walls (82, 83) structure sandwich consisting of two thin skins made of composite material with fiberglass reinforcement and a core constituted by an element made of foam of polymer material, or of a material with a honeycomb structure, or of a wood of balsa type. 10.Structure according to any one of the preceding claims, characterized in that the lateral reinforcing elements have a sandwich structure consisting of two thin skins made of composite material with fiberglass reinforcement and a core consisting of an element made of foam of polymeric material or material of honeycomb structure, or a balsa type of wood. 11.Structure according to any one of the preceding claims, characterized in that the various elements of said structure comprise rims arranged to allow the assembly of said elements by gluing and / or bolting and / or riveting, two elements (317 , 318) joined to each other having flanges (74, 75, 84, 85) arranged to face each other at the time of assembly.