CA2652129A1 - Flexible frame for a shelter - Google Patents

Abstract

A frame for a shelter serves to support a covering that is resistant to adverse weather. The frame comprises a series of ribs arranged in succession, each of the ribs having first and second lateral load-bearing elements that rest upon the ground, as well as a joining element that joins the first load-bearing element to the second load-bearing element. Each of the ribs can angularly move relative to at least one of the adjacent ribs. The frame also comprises variable-length spacer elements that are each connected between the joining elements of two successive ribs. The length of each spacer element can be varied in order to adjust the space between the joining elements of two successive ribs.

Description

TITLE OF THE INVENTION: FLEXIBLE ARMATURE FOR SHELTER

ANTERIORITY DATA

This patent application claims the conventional priority of the US Provisional Application No. 60 / 693,069 filed June 23, 2005.

FIELD OF THE INVENTION

The present invention relates to outdoor shelters, and more particularly to a flexible frame for outdoor shelters.

STATE OF THE ART

Road vehicle owners regularly install shelters outside the approach of the winter season, for example in their driveway, for to have a Covered parking space and protected from the snow.
These shelters are usually erected temporarily, usually during month of the year when snowfall is common. Once the months of past snow, shelters are: disassembled and stored, and only to be reused during the year next.
These shelters to be assembled and dismounted each year, it is desirable to make so that these shelters are easy to assemble. It is also desirable to make sure that the shelter is flexible so that it can adapt to the irregular shapes of the surface on which he is installed.
There are currently outdoor shelters of all kinds, but they missing generally flexibility.

SUMMARY OF THE INVENTION

The present invention relates to a frame for shelter, said frame destined to withstand a weather-resistant coating and comprising:

a series of ribs sequentially arranged, each of said ribs comprising first and second lateral support members intended to rest against the ground, as well as that an organ of link connecting said first carrier member to said second carrier member, each of said ribs being angularly mobile with respect to at least one of the ribs adjacent;

2 spacing members of variable length, each of said members spacing being connected between said connecting members of two successive ribs;
characterized in that the length of each of said spacers may be varied for adjust the spacing between the connecting members of two successive ribs.
In one embodiment of the invention, the armature further comprises connection means connecting pivotally and spaced apart said ribs to the successive coast, each coast of a pair of successive coasts being so angularly mobile compared to the other coast.
One of the embodiments of the invention is characterized:
in that said first and second bearing members of each of said ribs respectively comprise a first carrier rod and a second rod carrier irespectively, each of said carrier rods defining an end superior and a lower end resting on the ground, in that each of said connecting members defining a first end and a second end, and in that for each of said ribs, said first end of said liaison body is connected to said upper end of the first carrier rod, and said second end of said connecting member is connected to said upper end of said second carrier rod.
One of the embodiments of the invention is characterized in that means of corulexion comprise a series of first and second spacers to length predefined, each of said first struts connecting said first stems carrying two successive ribs, and each of said second struts connecting said second stems carrying two successive ribs.
One of the embodiments of the invention is characterized in that spacers are Folding and formed of two iron-angles connected in pivoting.
One of the embodiments of the invention is characterized in that said spacers are of constant length and define two opposite ends, each said ends first spacers being connected to a pivot located in the vicinity of the lower end said first carrier rods, and each of said ends of second spacers being connected to a pivot located near the lower end said second stems carriers.

3 One of the embodiments of the invention is characterized in that an axis of pivoting passes through the two so-called pivots of the same said coast, and in that these axes of pivoting of all said ribs are all parallel to each other.
One of the embodiments of the invention is characterized:

in that said connecting means comprise, in addition, a series of first and second stabilizing chords, each of said chords stabilization having a first end and a second end; and in that said first end of each of said first and second members stabilizer is pivotally connected in the vicinity of the end superior of said first and second carrier rod respectively of one of said ribs, and said second end of each of said first and second ribs of stabilization is pivotally connected to said pivot of said first and second shanks carrier respectively from the neighboring coast.
One of the embodiments of the invention is characterized:

in that each of said carrier rods defines a main portion elongated and a upper end portion angled to said main portion elongated;
in that said first end of each of said chords stabilization is ~ pivotally connected to the vicinity of the upper end of the portion primary an extension of a said corresponding carrier rod; and in that each of said stabilizing chords is arranged substantially symmetrically with respect to said elongated main portion of said rod better than which sadite first end is connected.
One of the embodiments of the invention is characterized:

in that each of said connecting members comprises a first and a second crossbowman each defining a long portion and an angled end portion, part bent end of said first and second rafters of one of said liaison bodies being coaxially coupled to said upper end portion said first and second corresponding carrier rods;

in that said upper end portion of each carrying rod as well as that part the bent end of said coupled connecting member are in a bisector of an angle formed between the elongate main part of the corresponding carrier rod and the chord corresponding stabilization.

4 One of the embodiments of the invention is characterized in that said member Variable Length Spacer includes a telescopic ridge defining a first end and a second end, each of these ends being connected to one of connecting members of two successive ribs, said telescopic ridge being to be lying down and shortened and thus defining an adjustable telescopic length, said telescopic ridge comprising locking means engageable to prevent any variation of said telescopic length.
One of the embodiments of the invention is characterized in that said ridge telescopic comprises a first tubular shaft, and a second rod mounted sliding in said first tubular shaft, said blocking means having a adjustment screw being able to be clamped to prevent said second rod from sliding by report to said first tubular stem.
One of the embodiments of the invention is characterized in that each said binding members has two rafters connected each in pivoting to a block of comlexion.
One of the embodiments of the invention is characterized in that the first end of each said telescopic ridge comprises a hook, in that each of said blocks connection comprises a handle, and in that the second end of each said telescopic is pivotally connected to said connecting block of one said ribs, and the second end of this ridge is connected to the connection block of one of the neighboring coasts by engagement of said hook in said handle.
One of the embodiments of the invention is characterized in that each said connecting members is detachably connected to the first and second bearing organs corresponding sides.

BRIEF DESCRIPTION OF THE DRAWINGS
In the accompanying drawings:
Figure 1 is a front perspective view of the shelter of the present invention, whose coating has been partially cut to show the sub-frame core;
Fig. 2 is an enlarged view of encircled area II-II of Fig. 1;
Figures 3-7B are perspective views showing sequentially the assembly of the shelter;

FIG. 8 is an enlarged perspective view of the front portion of the block of connection;
Figure 9 is an enlarged perspective view of the rear portion of the block of connection;

Figure 10 is a plan view of the assembled connection block, showing partially two rafters pivotally mounted thereon;
FIG. 11 is an enlarged perspective view showing in close-up the comlexion of a telescopic ridge between two neighboring coasts;
Figure 12 is a side elevational view of the shelter installed on a area irregular.

DETAILED DESCRIPTION OF THE ACHIEVEMENTS OF THE INVENTION

FIG. 1 shows an outer shelter 20 comprising a frame 22 on which is attached a coating 24. Hereinafter, the front of the shelter will refer to the foreground end of Figure 1, the back of the shelter will refer to the end in the background in Figure 1.
The outer shelter 20 is intended to be installed seasonally, during the months snow-covered, on an outdoor parking area of a residence. This genre shelter allows specifically, to avoid the accumulation of snow on the parking lot, and consequently avoids the holder to have to clear snow from his parking area and / or his vehicle following a fall of religion. This use is the traditional use of the shelter of the present invention, but is understood that the illustrated shelter could be used in any other situation, inside comane outside, to provide a sheltered space.
The coating 24 is of conventional manufacture; coatings for like shelters are usually made of impervious material, made of plastic or a material plasticized for example, to prevent the infiltration of water into the shelter.
The frame 22 consists of a series of U-shaped tubular ribs 26 inverted, these ribs being all interconnected as described below.
Each coast 26 is consisting of lateral carrying members, more particularly the rods carriers 28, 28 '. The stems carriers 28 and 28 'are mirror images of each other, and only the carrying rods 28 will described in detail below to avoid redundancy. More generally in following the this description, since the frame 22 is a structure symmetrical and has so a series of symmetrical elements, a single element of a pair of elements symmetric will be

6 described in detail, to lighten the text and figures. Symmetrical counterpart of the element described in detail will bear the same number as this one, but will be followed by a bonus ( ').
Each carrier rod 28 is formed of a linear main portion 28a, merging at its upper end with an upper end portion 28b, this last being comlinked at an angle, ie deviates from the axis of the main linear part 28a.
A fastener 28c male protrudes coaxially from the upper end portion 28b.
Each rib 26 further includes a connecting member 30 making the bridge enter its two carrying rods 28 and 28 '. These connecting members 30 are constituted two crossbowmen 32, 32 ', made of tubular metal for example. Each crossbow 32, 32 ' has a part 32a, whose inner end is pivotally mounted to a block of connection 60 (described in more detail below). The outer end of the long part 32a merges with a part bent 32b. The bent portion 32b being tubular, it constitutes a fastener female that can be slipped and fastened around the male fastener 28b a carrier rod 28 corresponding. A strong but detachable attachment between the crossbowman and the carrying rods 28, 28 'is preferable but optional. Such a strong fixation can be realized, for example, in sizing the male fastener 28c and the bent portion 32 and for that they fit in tight with each other, thus avoiding friction easily detach one from the other. In addition, the connecting members 30 comprise a cable 36 attached to both ends approximately at the center of the long portion 32a of the rafters 32.
This cable 36 will offer a surplus strength and stability to the connecting member 30, when the shelter is assembled and in use.
The ribs 26 are arranged successively, in a row, and are all connected to each other. The link between each pair of successive ribs is realized on the one hand by folding struts 40, 40 ', pivotally mounted in the vicinity of extremities lower of the carrier rods 28, 28 ', and this between each pair of ribs 26, 26 successive.
Each folding spacer 40 comprises two iron-angles 40a, 40b connected in pivoting one to the other at one of their extremities, the other end of each of the angles 40a, 40b being corvnectée in pivoting with the carrying rods 28, 28 of two ribs 26, 26 neighboring, so as to able to pivot about the axes 41, 41 (Figure 1, 7A-7B). Each spacer 40 can bend to the top (see Figure 7A), and can take two positions:
= a storage position (see Figure 3, where all but one of the spacers are folded), where the iron-angles 40a and 40b of the spacer 40 are folded one over the other and where the two stems carriers 28, 28 connected by this same spacer 40 are brought together and touch, and

7 = an unfolded functional position (Figure 2), in which the iron angles 40a, 40b are coaxial, and in which the two carrying rods 28, 28 connected to the ends of the iron 40a, 40b of the spacer 40 are spaced from each other.
All the spacers 40 of the frame 22 - with the exception of the last brace 40-z - have the same length in the operative position, and so allow a constant spacing between the axes 41 and between the end portions lower of each pair of carrier rods 28, 28 in succession.

All the bearing rods 28 and 28 ', except for the carrying rods of the first rib (nurnumbered 26-a in Figure 1) and the last rib (numbered 26-z on FIGS. 1, 7A-7B), are each connected to two spacers 40: a first spacer 40 connecting the rod carrier 28 to the successive carrier rod located towards the front of the frame 22, and a second spacer 40 connecting the carrier rod 28 to the successive carrier rod located towards the back of As illustrated in Figure 2, the iron angle 40b of the first spacer and the iron angle 40a of the second spacer are connected to the same pivot (not shown) on the carrying stem 28, so as to pivot about the same pivot axis 41.
In addition, the frame 22 comprises stabilizing members 42, 42 ', each 42 (or 42 ') being diagonally disposed between a pair of rods carriers 28, 28 (or 28 ', 28') successive. The upper end of the frame 42 is connected in pivoting to the upper end of the linear main portion 28a of a rod carrier 28, and the end bottom of the frame 42 is pivotally connected to the carrier rod 28 located immediately backwards, to the same pivot which connects the iron-angles 40b and 40a of two spacers 40 successive. The stabilizing ribs 42 can therefore they also rotate around a pivot axis 41 corresponding.
As illustrated in Figure 12, the linear main portion 28a of the rods carriers 28 is tilted towards the rear of the shelter when the frame is assembled. The chord 42 - which connects the upper end of this linear portion 28a to the portion bottom end of the coast 26 located immediately to the rear - is arranged substantially symmetrically by i-input to the linear part 28a, so that the linear part 28a, the frame 42 and the underlying spacer 40 together form a triangle substantially isosceles. In addition, the part bent 32a of the bowman 32, connected in the extension of the end portion upper part of the carrier rod 28, coincides substantially with the bisector of the formed angle between the linear portion 28a and the attached frame 42, which is normal to the ground. This arrangement allows a better distribution of the weight to bear between the carrying stem 28 and the

8 member 42 attached thereto, and thus gives a good bearing capacity to the walls lateral of 22. This characteristic is advantageous because in winter, the roof of the shelter is likely to covered with snow, and the shelter must be able to support adequately the weight of this accumulated snow.
The bearing rods 28-z and 28-z 'of the last rib 26-z, comprise as they two support legs 43, 43 'resembling the frames 42, 42' but whose the end lower leans against the ground rather than being connected to a rib adjacent. The dimensioning of the support legs 43, 43 'may differ from that of the frames of stabilization 42, 42 '. This is well illustrated in Figure 12, where we see that the last spacer 40-z is shorter than the others and we see the support leg 43 supported against the ground. We can also see that the support leg 43 is substantially vertical when the spacer is déplliée; this allows the back of the shelter to be leaned against a wall (for example the wall around the door of a garage entrance) without the legs interfering.
In addition, each connecting member 30 of the armature 22 is connected to the adjacent links by means of spacers with variable length, plus especially by telescopic racks 50 (shown in close-up in Figure 11). The rites telescopic 50 all extend between two connection blocks 60, 60 of two ribs 26 neighbors.
Each connection block 60, illustrated in detail in FIGS. 8-10, is composed of of two portions. The front portion 62, with an L-shaped section, is illustrated in FIG.
Figure 8. She corr: iprend a facade 64 in which is formed a handle 65, and in which are practiced two holes 76a, 76a ', on either side of the handle 65. The front portion 62 has a surplus upper wall 66 protruding transversely from the upper edge of the facade 64. The block of connection 60 also includes a rear portion 68 (FIG. 9) defining two fins 70, 70 ' in which holes 76b, 76b 'are formed, aligning with the holes 76a, 76a 'of the front portion 62 of the connection block 60 when it is assembled. The fins 70, 70 'are located on either side of an indentation formed (1) of two lateral walls 74, 74 'connected to the inner flange of a corresponding wing 70, 70 ', and (2) a bottom wall 72 bridging between the rear edges of the two side walls 74, 74 '. A pivot 75, under form of a dowel cylindrical, extends between the spaced lateral walls 74, 74 (FIGS. 9-10).
The rear portions and avaiit 62 and 68 respectively are assembled with two screws 78, 78 ' (Figure 10), crossing each, in order: (1) a hole 76a (or 76a '), (2) a hole (not shown) practiced in the portion inner end of the long portion 32a (or 32a ') of a crossbow 32 (or 32 '), and (3) the hole 76b (or 76b ') of the rear portion 68. Nuts 79, 79' are screwed onto the end of the screws 78,

9 78 ', for securing the two portions 62, 68 of the connection block 60, and that crossbowmen 32, 32 '.
The telescopic ridge 50 is pivotally mounted to the rear portion 68 of the block of connection 60 using the stud 75. The telescopic ridge has two bars tubulars: a fixed bar 52, one end of which is pierced and traversed by the pivot 75 of the block corvaexion 60, and a sliding bar 54, of smaller diameter, sliding climb in the internal cavity of the fixed tubular bar 52. The sliding bar 54, at its free end, is inunie of a hook 55 L-shaped (Figure 4).
The telescopic ridge 50 can be shortened or lengthened by sliding bar inward or outward of the fixed bar 52. When the desired length is reached, an adjustment screw 53 (shown in close-up in FIG. 11), secured to the fixed bar 52, can be tightened to immobilize the sliding bar 54 with respect to the fixed bar 52.
A telescopic ridge 50 is attached to the rear portion 68 of the block of connection of all the connecting members 30, with the exception of the last connecting member 30-z (Figure 7A-7B). The hook 55 of the ridge 50 of the connecting member 30 of a given rib 26 is intended to fit into the handle 50 of the connecting block 60 of the successive slope 26 and located towards the rear.
The installation of shelter 20 will now be described. When disassembled, the organs of link 30 are detached from the carrier rods 28, 28 '. The spacers 40 (and 40 ') are folded in storage position, and the carrying rods 28 (and 40 ') are all juxtaposed with each other others in a compact assembly (see Figure 3). The connecting members 30, when dismantled, can be stored in a compact configuration by swiveling both crossbowmen one to the other.
To assemble the frame 22 of the shelter, the two compact assemblies of rods carriers 28, 28 'are erected (arrows A in FIG. 3), then their paw of support 43, 43 'is drawn to the opposite of the last carrier rod 28-z, 28-z 'so that their lower end come and lean against the ground. The spacers 40-z, 40-z 'are thereafter unfolded if necessary so that the two iron-angles that constitute it are well coaxial (arrows B). The behind the 30-z linker is then unfolded as suggested by the arrows C in Figure 3, and the bent portions 32b-z of the two rafters 32-z, 32'-z are threaded, one after the other, on the male fasteners 28c-z at the upper end of the carrier rods 28-z, 28-z '(arrows D). Once the connecting member 30-z is in place, the long portion 32a-z of the crossbowmen boggles conl? re the upper wall 66-z of the 60-z connection block, and the 36-z cable is tense.

Subsequently, the following connecting member 30 is installed, as illustrated in FIG.
Figure 4.
The rafters 32, 32 'are first connected to the carrier rods 28, 28' respectively. The carrier rods 28, 28 'to which the connecting member has just been connected are then spaced the last carrier rods 28-z, 28-z '(arrows E), and the spacers 40, 40 'are unfolded in 5 functional position. Subsequently, the telescopic ridge 50 of this body link 30 is corvlected at the 60-z connection block of the last connecting member 30-z. For this to do, you have to turn the ridge 50 towards the connection block 60-z (arrow F in FIG. 5), the adjustment screw 53 is loosened (arrow G in Figure 6), then the ridge is shortened or lying down (arrow H of the FIG. 6) so that the hook 55 carried at its free end is aligned with the handle 65-

10 z of the connection block 60-z of the adjacent side 26 located rearwardly. The hook 55 is then engaged in the handle 65-z (arrow I of Figure 6).
The same sequence is then repeated (FIG. 7A, 7B) to assemble each ribs 26, and to connect each of these ribs 26 to the adjacent ribs by Reasons telescopic 50, until the frame 22 is completely assembled.
Once the ribs fully assembled, adjustment screws 53 telescopic 50 are all tightened, to solidify the frame 22.
Subsequently, the coating 22 is placed on the frame, and is attached to way corwentionnelle. Concrete blocks or sandbags can then be posed around the lower end of some or all of the carrier stems, for to anchor well removable or not, the shelter on the installation surface, as known from the to do for this guy shelter.

To disassemble the shelter and store it, the steps previously described are followed but in the reverse order. If the user does not wish to store the shelter but simply retract it in a compact configuration while keeping it on the site of installation, it is possible to pick up all the hooks 55 corresponding 65 handles, and fold back the spacers 40 of so that all the ribs 26 come together and juxtapose in one compact assembly.
The shelter can remain outdoors in this compact configuration when the shelter is not used - for example during the months when it is not snowing - rather than being stored.
One advantage of the shelter according to the present invention is its flexibility and its ability to settle steadily on an uneven surface, such as on the surface variable slope of the FIG. 12. Indeed, each of the ribs 26 can pivot with respect to the axis of pivoting 41 of the rear adjacent coast, and each side 26 is thus angularly movable by compared to the ribs

11 neighbors. Thus, the angles al - a6 formed between each pair of ribs successive 26, 26 may vary according to the slope of the surface on which the armature 22 is installed.
The value of the angle that will be formed between each pair of adjacent ribs 26, 26 is function of the geometry of the installation surface, and therefore can not always be determined beforehand. Consequently, the distance between the connecting members of each pair of ribs neighboring countries is also variable and can not be determined either before assembling the arrnature. By providing spacing spacers - the doing telescopic 50 - between each pair of connecting members 30 successive, the shelter can adapt to relief of the surface on which it is installed. Indeed, when the screws Adjustment 53 telescopic 50 are loose, the telescopic racks can be adapted to the distance between connecting members of each pair of neighboring coasts, determined on the site installation in function of the slope of the surface on which the armature is installed.
It is understood that the realization of the invention described above and represented on the figures is an exemplary embodiment, and that many variations could be considered while remaining within the scope of protection described in the claims attached.
For example, the carrier rods 28, 28 'could be replaced by anything what other form of appropriate carrier organ.
In addition, telescopic racks could be replaced by any other spacing member with variable length, which makes it possible to adapt the spacing variable between each pair of successive connecting members.
Moreover, the link between the carrying rods of each pair of ribs clear could be realized differently than by spacers and frames of stabilization.
Any form of liaison that would be thought of by a person domain of the invention could be used, as long as it allows a movement relative angular of the ribs one against the other.
Alternatively, these means of connection could be omitted, the distance enter the rods carrying the ribs being then determined by the user during installation. The ribs could each rotate around an axis passing through their colon ground support (the lower end of the carrying rods). Alternatively, the end lower stems carriers may not rest directly on the ground, but rather heavy soles resting on the ground. In such an embodiment, the ribs could be angularly mobile one another by pivoting around a hinge connecting the carrying rods to soles.

Claims (15)

1. A frame for a shelter, said frame for supporting a covering resistant to weathering and including:
a series of ribs sequentially arranged, each of said ribs comprising first and second lateral support members intended to rest against the ground, as well as that an organ of link connecting said first carrier member to said second carrier member, each of said ribs being angularly mobile with respect to at least one of the ribs adjacent;
spacing members of variable length, each of said members spacing being connected between said connecting members of two successive ribs;
characterized in that the length of each of said spacers may be varied for adjust the spacing between the connecting members of two successive ribs. 2. The reinforcement according to claim 1, further comprising connection means pivotally connecting and spaced way each of said ribs to the next rib, each of the ribs of a pair of successive ribs being thus angularly mobile with respect to the other side. 3. The reinforcement according to claim 2, characterized in that said first and second bearing members of each of said ribs respectively comprise a first carrier rod and a second rod carrier respectively, each of said carrier rods defining an end superior and a lower end resting on the ground, in that each of said connecting members defining a first end and a second end, and in that for each of said ribs, said first end of said liaison body is connected to said upper end of the first carrier rod, and said second end of said connecting member is connected to said upper end of said second carrier rod. 4. The reinforcement according to claim 3, characterized in that said connecting means comprises a series of first and second spacers with predefined length, each of said first connecting struts said first rods carrying two successive ribs, and each said second spacers connecting said second rods carrying two ribs successive. 5. The reinforcement according to claim 4, characterized in that the spacers are bendable and formed of two fer-connected angles in pivoting. 6. The reinforcement according to claim 4, characterized in that said spacers are of constant length and define two opposite ends, each of said ends of the first spacers being connected to a pivot located in the vicinity of the lower end of said first rods carriers, and each said ends of the second spacers being connected to a pivot located at the neighborhood of the lower end of said second carrier rods. 7. The reinforcement according to claim 6, characterized in that a pivot axis passes through both said pivots of the same coast, and in that these pivot axes of all said ribs are all parallel between them. 8. The reinforcement according to claim 6, characterized in that said connecting means comprise, in addition, a series of first and second stabilizing chords, each of said chords stabilization having a first end and a second end; and in that said first end of each of said first and second members stabilizer is pivotally connected in the vicinity of the end superior of said first and second carrier rod respectively of one of said ribs, and said second end of each of said first and second ribs of stabilization is pivotally connected to said pivot of said first and second shanks carrier respectively from the neighboring coast. 9. The reinforcement according to claim 8, characterized in that each of said carrier rods defines a main portion elongated and a upper end portion angled to said main portion elongated;
in that said first end of each of said chords stabilization is pivotally connected near the upper end of the portion primary elongate of a said corresponding carrier rod; and in that each of said stabilizing chords is arranged substantially symmetrically with respect to said elongated main portion of said rod better than which sadite first end is connected. 10. The reinforcement according to claim 9, characterized:
in that each of said connecting members comprises a first and a second crossbowman each defining a long portion and an angled end portion, part bent end of said first and second rafters of one of said liaison bodies being coaxially coupled to said upper end portion said first and second corresponding carrier rods;
in that said upper end portion of each carrying rod as well as that part the bent end of said coupled connecting member are in a bisector of an angle formed between the elongate main part of the corresponding carrier rod and the chord corresponding stabilization. 11. The reinforcement according to claim 2, characterized in that said variable length spacer comprises a ridge telescopic device defining a first end and a second end, each of these ends being connected to one of the connecting members of two ribs successive, said ridge which can be lengthened and shortened and thus defining a telescopic length adjustable, said telescopic ridge comprising locking means be engaged for prevent any variation of said telescopic length. 12. The reinforcement according to claim 11, characterized in that said telescopic ridge comprises a first rod tubular, and a second rod slidably mounted in said first tubular rod, said means of blocking comprising an adjustment screw that can be tightened to prevent said second rod slide relative to said first tubular shaft. 13. The reinforcement according to claim 11, characterized in that each of said connecting members comprises two crossbowmen connected each pivoting to a connection block. 14. The reinforcement according to claim 13, characterized in that the first end of each said telescopic ridge has a hook, in that each of said connection blocks has a handle, and what the second end of each of said telescopic racks is connected in pivoting to said block of connection of one of said ribs, and the second end of this ridge is connected to the block of connecting one of the adjacent ribs by engaging said hook in said handle. 15. The reinforcement according to claim 1, characterized in that each of said connecting members is connected with detachable way to first and second corresponding lateral carrier members.