FR2638707A1 - Balloon gondola made of composite materials, configured for transporting heavy loads - Google Patents

Abstract

In order to allow the transporting of heavy loads, especially so as to carry out flights of long duration, the gondola of a balloon is produced in composite materials. More precisely, the gondola includes a cockpit, reinforcing plates 12, and, optionally, longitudinal tubes 14 passing through the plates and by which the gondola can be suspended from the balloon. In order to avoid the cockpit bursting on landing, a landing structure, formed by a tubular frame 20, is mounted under the reinforcing plates 12.

Description

Aerostat platform made of co-posite materials, suitable for transporting heavy loads.

DESCRIPTION
The invention relates to an aerostat nacelle, particularly suitable for transporting heavy loads.

 The word "aerostat" here designates aerostats of all types and includes in particular hot air balloons.

 Usually, the pods of aerostats are made of wicker. The use of this material is explained by its low weight and by its deformable nature, which prevents the nacelle from rupturing on landing.

 However, wicker baskets do not allow the transport of heavy loads. In particular, the resistance of the nacelle does not allow carrying loads greater than about 200 kg at takeoff. The duration of the flights is therefore necessarily short since it is practically impossible to take on booster tanks authorizing long-term flights.

 The invention specifically relates to a nacelle of a new type, made of composite materials allowing, thanks to their low weight and their high resistance, to carry loads much heavier than wicker nacelles, which allows including long-term flights.

 The subject of the invention is also a composite material platform made in such a way that the lack of flexibility of the composite materials allowing the transport of heavy loads is compensated by the presence of a deformable landing structure.

 According to the invention, these various objectives are achieved by means of an aerostat nacelle, characterized by the fact that it comprises a cabin resting on at least two rigid U-shaped reinforcing plates, parallel to each other, and a deformable landing structure, mounted under the reinforcing plates so as to be able to come to bear on the ground in four zones situated outside the projection of the passenger compartment on a plane passing through these four zones, the passenger compartment, the plates and the landing structure being made of composite material.

 In a preferred embodiment of the invention, the landing structure comprises two lateral skids located in two planes oriented downward and outward relative to the passenger compartment, each of these skids comprising a central part connected to the reinforcement plates and two end portions curved downward and outward relative to the passenger compartment, to define said zones.

 Advantageously, the naceLle further comprises two longitudinal tubes passing through the reinforcement plates on either side of the passenger compartment, slightly below the bottom of the latter, these tubes being fixed to the reinforcement plates and comprising, in the vicinity of their ends, hooking means for cables by which the nacelle is suspended from an aerostat, these tubes also being made of composite material.

A preferred embodiment of the invention will now be described, by way of nonlimiting example, with reference to the accompanying drawings, in which:
- Figure 1 is a perspective view showing a nacelle of composite materials according to the invention;
- Figure 2 is a side view of the nacelle of Figure 1, in section along the line Il-Il of Figure 3, after read in place onboard equipment and booster tanks;
- Figure 3 is a top view of the nacelLe of Figure 2; and
- Figure 4 is a perspective view showing on a larger scale one of the fittings for fixing the tubular frame forming the landing structure on each of the reinforcement plates of the nacelle.

 As illustrated in FIGS. 1 to 3, the aerostat nacelle according to the invention comprises a compartment 10 resting on two rigid reinforcing plates 12, flat and parallel to one another. The plates 12 each have approximately the shape of a U and they are oriented transversely relative to the naceLle. The attachment of the passenger compartment 10 to the plates 12 is carried out by any appropriate means, for example angles glued to each of these parts.

 In the exemplary embodiment illustrated in the figures, the passenger compartment 10 has a flat bottom, two flat and parallel side walls and two flat end walls which approach one of the other upwards. It is made of a sandwich composite material comprising a honeycomb core and coverings made of Kevlar fibers, linked by an epoxy resin, which makes it light and resistant.

 The reinforcing plates 12 are also made of a sandwich composite material comprising a honeycomb core and carbon fiber coatings, bonded by an epoxy resin. The good resistance and stiffness characteristics of carbon fibers improve the rigidity of the nacelle. Although two reinforcing plates are provided in the example described, the number of these plates can be greater than two.

 In the exemplary embodiment illustrated in the figures, the outer edges of the reinforcing plates 12 have notches in a circular arc 12a making it possible to fix on either side of the passenger compartment 10 tanks R illustrated in the figures 2 and 3. The fixing of the tanks to the plates can in particular be carried out by means of the angle brackets.

 Advantageously, the reinforcing plates 12 are traversed, on either side of the passenger compartment 10 and at a level slightly lower than that of the bottom of the latter, by longitudinal tubes 14, parallel to each other and to the side walls of the cabin.

 These tubes 14, which are also made of a composite material consisting of carbon fibers linked by an epoxy resin, are fixed to the plates 12 by any suitable means, and in particular by gluing.

 An anchoring fitting 16 is fixed near each of the ends of the tubes 14, that is to say beyond the passenger compartment 10. These fittings 16 serve to hang cables 18, through which the nacelle, on the longitudinal tubes 14 is suspended from the aerostat (not shown). The cables 18 are advantageously made of Kevlar fibers, which gives them a certain flexibility.

 The assembly constituted by the compartment 10, the reinforcing plates 12 and, optionally, the longitudinal tubes 14, forms a nacelle whose weight is close to that of a conventional wicker nacelle, and which makes it possible to transport heavy loads, for example around 1000 kg, aWhile the mechanical strength of a wicker basket only allows to carry loads barely exceeding 200 kg.

 However, such an assembly would break on landing, given the rigidity of the composite materials which constitute it, if it were not intended, in accordance with the invention, to add to it a suitable landing structure to deform at the dare of the landing to absorb the transai shock to the other elements of the nacelle, so that this shock is of no consequence on these elements.

 In the free embodiment illustrated in the figures, this deformable landing structure is constituted by a tubular frame 20. This frame 20 is also made of a composite material comprising glass fibers, linked by an epoxy resin.

 The structure of the frame 20 is such that it has four zones Z of contact with the ground, located in the same plane parallel to the bottom of the passenger compartment 10. These four zones are located outside relative to the projection of the passenger compartment on this plane, as illustrated in FIG. 3, which ensures good stability for the nacelle when it is on the ground.

 More specifically, the tubular frame 20 forms two lateral pads which are located in two planes arranged symmetrically on either side of the passenger compartment and oriented downwards and outwards relative to the latter.

 The portion of the frame forming each of these pads comprises a rectilinear central part 20a, parallel to the bottom and to the side walls of the passenger compartment, and two end parts 20b curved downwards and outwards relative to the passenger compartment. The parts 20a serve to mount the frame 20 under the plates 12, in a manner which will be described later. The end portions 20b are oriented approximately 600 outwards (FIG. 2) relative to the vertical, when the bottom of the passenger compartment is horizontal, and they terminate in the contact zones Z. In addition, the planes in which are located The side pads are oriented approximately 450 outwardly from the vertical, When the bottom of the passenger compartment is horizontal.

 In addition to the side runners, the tubular frame 20 includes two end portions 20c which connect the runners. These end portions 20c are bent upwards and towards the passenger compartment 10 from the zones Z, to form an inverted U as illustrated in FIG. 2. This configuration makes it possible to protect the passenger compartment in the event of partial overturning of the nacelle on landing.

 Each of the central parts 20a of the tubular frame 20 is mounted under each of the reinforcing plates 12, approximately between the passenger compartment 10 and the tubes 14, by fittings 22 whose structure is shown in more detail in FIG. 4.

 Each fitting 22, made for example from a light metal such as aluminum, is formed by two half-fittings 22a assembled by bolts 24.

 In their lower part, the half-fittings 22a comprise parts 22a1 forming complementary half-cylinders between which is trapped The part 20a of the tubular frame 20, when the bolts 24 are in place. In the embodiment illustrated in the figures, the part 20a is clamped between the two half-fittings 22a and preferably glued, so that the frame 20 is fixed on the fittings 22.

 As a variant, the part 20a can be immobilized in translation in the fitting, while having the possibility of rotation relative to the latter. There is then a clearance between the parts 22al and the part 20a, and the beads 26 illustrated in phantom in Figure 4 are then mounted on the part 20a, on either side of the fitting. These beads 26 can in particular be ligatures made with wire.

 In their upper part, the half-fittings 22a comprise flat parts 22a2, parallel to each other and separated by a distance slightly greater than the thickness of the plates 12. When the two half-fittings are assembled by means of bolts 24, the parts planes 22a2 are aligned and form a U-shaped notch, oriented perpendicular to the axis of the part 20a of the tubular frame, and into which the lower edge of the corresponding reinforcement plate 12 can be introduced.

 The fixing of the plates 12 in the notches thus formed is ensured by bolts (not shown) passing through aligned holes drilled in the parts 22a2 and in the plates 12.

 When the aerostat lands, the nacelle according to the invention comes into contact with the ground by the intermediary of the landing structure formed by the tubular frame 20.

Specifically, when each of the zones
Z of the frame 20 comes into contact with the ground, there is a bending of the parts 20b which has the effect of simultaneously increasing the inclination towards the outside of the planes of the lateral runners formed by the frame and the inclination towards the outside end portions 20b of the pads in this plane.

 In the case where the frame 20 is fixed to the fittings 22, the amplitude of this increase in inclination is limited by the torsion of the parts 20a of the frame and by the resistance opposed by the end parts 20c. Optionally, these latter parts can then be removed, so that the landing structure then consists of two separate lateral pads.

 In the case where the frame 20 is only immobilized in translation in the fittings 22, the amplitude of the inclination attachment of the parts 20b is only limited by the resistance opposed by the end parts 20c.

 In all cases, the shock produced by the landing is absorbed by the landing structure, so that the passenger compartment 10 and the reinforcing plates 12 do not suffer any damage.

 It should be noted that the strong inclination of the parts 20b as well as the very eccentric arrangement with respect to the passenger compartment of the zones Z allow landings to be made on sloping ground, without damage to the landing structure.

 Advantageously, any bending of the longitudinal tubes 14 by which the nacelle is suspended from the aerostat can be compensated for by the presence of shrouds attached to the ends of these tubes and bearing under the plates 12.

 In an alternative embodiment not shown, safety connection cables can be provided between the tubes 14 and the frame 20.

 In another variant, the tubes 14 are eliminated and the nacelle is attached to the aerostat directly on the tubular frame 20.

 The fittings 22 connecting the frame 20 to the plates 12 can also be omitted, the tubular frame then being connected to the longitudinal tubes by damping members of known type.

Claims (10)

 1. Aerostat nacelle, characterized in that it comprises a passenger compartment (10) resting on at least two rigid reinforcing plates (12) in the shape of a U, pa parallel to each other, and a deformable landing structure ( 20), mounted under the reinforcing plates so as to be able to come to bear on the ground in four zones (Z) situated outside the projection of the passenger compartment on a plane passing through these four zones, the passenger compartment, the plates and the landing structure being made of composite material.  2. Nacelle according to claim 1, characterized in that the landing structure (20) comprises two lateral skids located in two planes oriented downwards and outwards relative to the passenger compartment, each of these skids comprising a central part (20a) linked to the reinforcement plates (12) and two end parts (20b) curved downwards and outwards relative to the passenger compartment (10), to define said zones (Z).  3. A nacelle according to claim 2, characterized in that the planes of the side skids are oriented approximately 450 towards the outside and the end portions (20b) are oriented approximately 600 towards the outside.  4. Nacelle according to any one of claims 2 and 3, characterized in that the lateral pads are connected by two end parts (20c) curved upwards and backwards relative to the end parts (20b) pads, so as to form a tubular frame (20).  5. A nacelle according to claim 4, characterized in that the tubular frame (20) is made of glass fibers, linked by an epoxy resin.  6. A nacelle according to any one of claims 2 to 5, characterized in that the central part (20a) of the pads is mounted under each reinforcement plate (12) by a fitting (22) fixed on a lower edge of each plate and in which said central part (20a) is at least immobilized in translation.  7. Nacelle according to any one of the preceding claims, characterized in that it further comprises two longitudinal tubes (14) passing through the reinforcement plates (12) on either side of the passenger compartment (10), approximately at the bottom of the latter, these tubes being fixed on the reinforcement plates and comprising, near their ends, hooking means (16) for cables (18) by which the nacelle is suspended from an aerostat , these tubes (14) also being made of composite material.  8. A nacelle according to claim 7, characterized in that the longitudinal tubes (14) are made of carbon fiber, linked by an epoxy resin.  9. A nacelle according to any one of claims 1 to 8, characterized in that the reinforcing plates (12) are made of a sandwich composite material comprising a honeycomb core and carbon fiber coverings, bonded with an epoxy resin.  10. Nacelle according to any one of claims 1 to 9, characterized in that the passenger compartment (10) is made of a composite sandwich material comprising a honeycomb core and coverings of Kevlar fibers, linked by an epoxy resin.