Crash barrier for aircraft

Abstract

A crash barrier for an aircraft, which includes an array of elementary nets arranged parallel to each other. Each elementary net includes a generally vertical stop structure which extends between a first upper strap and at least one second lower strap. The first and second straps each includes two end portions for attaching to a braking device, wherein the end portions of the one and/or the other of the upper and lower straps includes a loosened intermediate section, that is, which is not tensed and which forms an overlength. The barrier includes an additional strap of which the opposite ends are fastened by linking means to the corresponding ends of the loosened intermediate section. The additional strap includes a region in which it is constituted by two distinct and contiguous strands. The binding wire, that is, the weft or warp wire of this additional strap being common to the two strands. The pull-out resistance of the binding wire being less than that of the linking means.

Claims

1. A crash barrier for an aircraft, comprising: an array of elementary nets arranged parallel to each other, each of said elementary nets comprising a generally vertical stop structure which extends between a first upper strap and at least one second lower strap, said first upper and second lower straps each comprising two end portions attached to a braking device, said two end portions of the one and/or the other of said upper and lower straps comprising a loosened intermediate section with opposite ends, which is not tensed and which forms an overlength; an additional strap with a binding wire, opposite ends-of said additional strap being fastened by linking means to the opposite ends of said loosened intermediate section; wherein said additional strap comprises a region which is constituted by two distinct and contiguous strands, the binding wire of said additional strap being common to said two distinct and contiguous strands, the pull-out resistance of said binding wire being less than that of said linking means.

2. The crash barrier according to claim 1, wherein said linking means comprise sewing wires.

3. The crash barrier according to claim 2, wherein said sewing wires extend over a length of at least 50 millimetres.

4. The crash barrier according to claim 1, wherein a total length of said loosened intermediate section is more than the total length of said additional strap when said strands are separated from each other.

5. The crash barrier according to claim 1, wherein said linking means are formed by adhesion.

6. The crash barrier according to claim 1, wherein said linking means comprises an assembly made by high-frequency welding.

Description

DESCRIPTION OF THE FIGURES

(1) Other characteristics and advantages of the invention will emerge from the following description in reference to the appended drawings which by way of indicative but non-limiting manner represent different possible embodiments, in which:

(2) FIG. 1 is a diagram showing a frontal view of a crash barrier for aircraft;

(3) FIG. 2 is a block diagram of the barrier of FIG. 1, in plan view;

(4) FIG. 3 is a block diagram, in perspective, of a barrier such as that of FIGS. 1 and 2;

(5) FIG. 4 is a diagram which aims to illustrate the structure and the operation of a solution according to the prior art which equips some crash barriers and which distributes the stresses applied by the latter to the aircraft to be stopped;

(6) FIG. 5 is a diagram similar to FIG. 4, but showing part of the solution according to the invention;

(7) FIG. 6 is an enlarged view of the zone of FIG. 5 marked by a circle;

(8) FIG. 7 is a simplified diagram, similar to that of FIG. 5;

(9) FIG. 8 is a graphic showing, as a function of the tension exerted on a net of a barrier, the elongation of a strap it is fitted with, and this according to the prior art;

(10) FIG. 9 is a graphic showing, as a function of the tension exerted on a net of a barrier, the elongation of a strap it is fitted with, and this according to the present invention;

(11) FIG. 10 is a graphic showing as a function of time on the one hand the displacement of individual nets together forming a crash barrier according to the invention and also the total of the supporting forces of the nets on an aircraft.

DETAILED DESCRIPTION OF THE INVENTION

(12) The present invention applies to a barrier BA such as the one described above. Consequently, what has been described earlier in relation to FIGS. 1 to 3 also applies to the following.

(13) The specificity of the barrier according to the invention forms the subject of the attached FIGS. 5 to 7.

(14) As in FIG. 4 above, the focus here is one of the end portions 20 of the upper strap 2, given that what is specified hereinbelow applies also for the second end portion of this strap 2, or even for the end portions 30 of the lower strap(s) 3.

(15) The illustrated portion 20 therefore comprises a loosened intermediate section 21, that is, one which is not tensed when the barrier is not being used.

(16) In keeping with the invention, this deals with an additional strap 6 of which the opposite ends 60 and 61 are fastened by linking means 64 (see FIG. 7) to the corresponding ends 210 and 211 of said loosened intermediate section 21.

(17) Advantageously, these linking means 64, which can consist for example of sewing wires, preferably extend over 50 to 200 millimetres. Other linking techniques 20 such as adhesion, assembly by high-frequency welding, etc. can be used here, of course.

(18) Still according to a characteristic of the invention, this additional strap 6 can comprise a region 62, situated preferably mid-distance from its ends 60 and 61, which is constituted by two strands 62A and 62B, to a certain extent forming distinct and contiguous elementary straps, joined together. In other words, the strap 6 is formed by two elementary straps 62A and 62B which are connected to each other in the region 62 where they are contiguous.

(19) The particular feature of these two strands (or elementary straps) 62A and 62B is that the binding wire, that is, the warp wire or the weft wire which connects it in the region 62 is common. They are to a certain extent interlocked with each other. This interlocking is preferably done during weaving of the strap 6. This type of additional strap can be qualified as tear strap.

(20) In keeping with the invention, the pull-out resistance of the above binding wire is less than that of said linking means 64, in this case sewing wires.

(21) In this way, once an elementary net 1 is subjected to force it is first of all the unattached parts of the strap 6 which will be tensed. Then, if this force increases, it is part of the binding wire of the upper part of the strands 62A and 62B which will give way as priority.

(22) This is illustrated symbolically in FIG. 6 showing that the upper parts of the strands 62A and 62B move away from each other.

(23) If the force remains stable, the separation of strands 62A and 62B stops at this point.

(24) But once the force increases, separation of the strands progresses and so on.

(25) Therefore, each elementary net 1 moves as a function of the stresses it undergoes, and this progressively and smoothly.

(26) Of course, provided the binding wire above gives way fully, the strands 62A and 62B are no longer contiguous, such that the entire intermediate section 21 is now not loosened but instead tensed. The braking device F can transmit the entire braking force to the elementary nets 1.

(27) To the extent where the stresses are not the same for all the elementary nets 1, each moves independently of the other, contributing individually and jointly to immobilisation of the aircraft, without affecting all its fragile parts.

(28) By way of indication and as illustrated in FIG. 7, the length l of each strand 62A and 62B is between 300 and 2000 millimetres, while the total length of the intermediate section 21 is between 1000 and 5000 millimetres.

(29) According to a characteristic of the invention, the total length of said loosened intermediate section 21 is more than the length of the strap 6 once the tear is complete, given the intrinsic elasticity of the material which constitutes the unitary straps of the strap 6.

(30) The attached FIG. 9 illustrates the behaviour of a net of a barrier according to the invention, compared to a net of a barrier according to the prior art of FIG. 4, as is illustrated in FIG. 8.

(31) These two figures show in abscissa the elongation of the elementary net 1 fitted with the strap 6 and in ordinates the progression of the tension to which this net is subjected. Also, the dashed line SD corresponds to the unloading threshold, that is, the tension beyond which the strands 62A and 62B separate according to the invention (respectively the straps 5A to 5C break according to the prior art).

(32) In FIG. 9, it is evident that the net 1 remains permanently taut and that any decrease in tension stops separation of the strands 62A and 62B. The net can elongate continually without ever fully loosening. The temporary losses in tension illustrated by the reference A correspond to the loading by other elementary nets of part of the braking force of the barrier. The reference B corresponds to the maximum programmed elongation of the elementary net, after the binding wire of the strands 62A and 62B has completely detached.

(33) In FIG. 8, it is evident that the three peaks C are enough to fully consume the extension reserve of the strap of the elementary net 1. The reference D corresponds to the maximum programmed elongation of the elementary net, after the straps 5A to 5C have fulfilled their shunt function.

(34) FIG. 10 is drawn from an engagement simulation test, that is, stopping of a plane (of which the known speed and mass yield the forces exerted on the elementary nets 1), which show twenty-four partial and successive separations of the strands 62A and 62B.

(35) Each curve C1 corresponds to an elementary net 1. The elongations of the nets are expressed in ordinates, whereas the time elapsing during these elongations are expressed in abscissa.

(36) The curve C2 corresponds to the sum of the reaction forces for ground-anchoring of the braking devices, the forces being in ordinates.

(37) The curve C3 corresponds to the total support forces of the nets 1 on the plane, the forces being in ordinates also.

(38) More precisely, on a curve C1, a mass movement of 100% can be observed, which corresponds to the tensing of the whole section 21 after the binding wire above is completely torn. This happens in under 0.5 second.

(39) For each other curve C1, multiple successive micro-plates are noted, which corresponds to progressive tears of the binding wire up to 0.75 seconds, then no more tearing (fixed lengths).

(40) It is clear that just before the final plate tears all are happening at the instant t=0.7 s. This means that the elementary nets at this stage almost all have different lengths.

(41) At around 0.7 s, many micro-plates are noticed showing that the load has dropped to below the tear threshold, and therefore that the elementary nets have loosened since they are no longer lengthening over a period of a few hundredths or tenths of a second.