FR2484013A1 - Joint between corrugated mine ventilation duct sections - is angle piece with ribbed sides bolted to ducting bridging peaks of one corrugation - Google Patents

Abstract

The joint between sections of corrugated ducting (1) such as mine ventilation shafts, is formed by sections (10) of sheet material, V-shaped in cross section. Each sheet section is curved to match the diameter of the duct. The two sloping sides (12,14) have short conical strengthening ribs (18) punched at regular intervals along their edges, with their pointed tips (19) terminating about half way across. This joint member is secured by bolts (20) passing through the sloping surfaces (8,9) of the corrugated duct underneath and secured by nuts. These bolts are located between the strengthening ribs. One joint member spans a single corrugation, and its height is at least 1.5 times the height of the corrugation. Its sheet can be the same thickness as that of the corrugated sheet.

Description

The present invention relates to flexible curved structures, such as metal nozzles, intended to be covered by an embankment in order to constitute passages under the surface of the ground.
These structures being subjected during their use to transverse forces due to the weight of the embankment and to mobile overloads must have sufficient flexibility to withstand transverse deformations without inconvenience, up to a state of equilibrium. However, these structures must also have sufficient stiffness to withstand the manipulations and lateral forces which appear, for example, during backfilling.
To meet these requirements, nozzles or other flexible structures are generally produced by assembling corrugated sheets of standardized dimensions, bent perpendicularly to the corrugations. These plates being interchangeable, their position in the wall is not predictable. The depth of the corrugations and the thickness of the sheet vary according to the structure to be made, but the sheet has of course a constant thickness over the entire periphery of the structure, which means that this thickness must be chosen according to the forces However, it is well known that the external pressures on flexible structures are not uniformly distributed and that certain zones of their sections are subjected to significant bending moments, while the rest of the periphery of these same sections are only subjected to clearly lesser moments Localized stresses, which can sometimes be very high, thus oblige to give the whole of the structure a very strong thickness compared to what is necessary elsewhere.

This results in improper use of the metal which results in a corresponding increase in the price of re comes from the assembly, but it also results in an impossibility of producing flexible works of very large size. The thickness of the corrugated sheets cannot be increased beyond a certain limit of the order of 8 to 10 mm, so that the production of flexible structures exceeding a diameter of the order of 8 to 10 meters, or likely to be subjected to extremely large forces, would only be possible by increasing the dimensions of the waves, which has drawbacks.

It has been proposed to provide flexible structures with stiffeners at their ends, or even to mount reinforcing elements on certain parts of the section of the duct, possibly by filling the cavities thus delimited with a stabilizing material, but these systems do not give not satisfactory results. For example, the reinforcing elements which each close a corrugation and are fixed thereon by small flat or folded edges have only a relatively local action which means that they have to be multiplied on the structure surface and reduced by the useful dimension of the tunnel.

The object of the present invention is to produce a nozzle which has greater stiffness in the zones which are liable to be subjected to high bending moments, by using only a small number of stiffeners which each act on a relatively surface extent and do not unnecessarily reduce the internal useful dimension of the structure.

 The object of this invention is in fact a flexible, curved structure made of corrugated sheet metal, the corrugations of which are perpendicular to the generatrices, which comprises at least one row of stiffeners spaced apart from one another in the longitudinal direction and extending over a portion of the perimeter of the cross section of the structure, which are each formed by a bent V-shaped and curved sheet, comprising on both sides of a ridge projecting from the surface of the structure, but coaxial with this last, two flanks, generally conical and in close contact with two different corrugations of the main sheet, which have at regular intervals bosses in cone portion, projecting outwards and flaring towards the edge of the remote side of the ridge, of the fastening members passing through these sides and of the main sheet between these projections.

 The stiffener is thus both in very close contact with at least two undulations of the structure, on at least part of their profile, and projecting with respect to these undulations, so that it forms a structure with the latter. in a box having great rigidity and reacting to bending like a composite beam, capable of withstanding significant bending moments.

 All the corrugations of the nozzle, or other flexible structure, being integral with one another, it is not essential that the stiffeners be placed side by side over the entire length; a spacing can be provided between the stiffeners of the same row, each stiffener having the effect of reducing the bending stress not only in the directly capped areas, but also on either side of these areas thanks to the postponement of the stresses d 'one wave to another.

Thanks to this arrangement, a flexible structure produced using a thin corrugated sheet can have sufficient stiffness in the zones subjected to significant bending moments. As a result, flexible works of very large dimensions can be produced using corrugated sheets of conventional thickness, while works of usual dimensions can be formed by means of corrugated sheets which are considerably less thick, that is to say - say at a reduced cost price.

The description below of an embodiment given by way of nonlimiting example will moreover highlight the advantages and characteristics of the invention.

In the accompanying drawings
- fig. 1 is a partial perspective view of a metal nozzle provided with a stiffener according to the invention;
- fig. 2 is a partial view in cross section of the nozzle and the stiffener;
- fig. 3 is a side view of a stiffener ready to be mounted;
- fig. 4 is a diagram of a flexible structure in place, showing the polar diagram of the bending moments which are exerted on this structure during backfilling;
- fig. 5 is a diagram similar to FIG. 4, showing the position of the stiffeners as a function of the moments which are exerted in service;
- fig. 6 is a schematic view in elevation of the teral, showing the position of the stiffeners along the length of the nozzle.

The invention relates to a flexible, curved structure, which may have a cylindrical shape with a circular, elliptical or other section, or even the shape of an arch or portion of a cylinder. This work is formed by an assembly of corrugated and curved sheets, so that it has circumferential undulations and comprises, along its generatrices, a succession of ridges 2, 4, 6 and hollows 3, 5, 7, joined together between them by flanks 8, 9.

The flexible structure 1 further comprises, according to the invention, at least one row of stiffeners 10 spaced from one another along the length of the nozzle (FIG. 6).

Each stiffener 10 is constituted, as shown in Figures 1 and 2, by a sheet of thickness similar to that of the main sheet of the nozzle 1, which is folded in V and covers at least two ridges 2 and 4 of this sheet main by projecting from the surface of nozzle 1.

This sheet 10 is also curved in the same way as the main corrugated sheet 1, so as to be coaxial with this plate.

According to a preferred embodiment, each stiffener 10 has two sides 12 and 14 joined by a crest 15. The sides 12, 14 are parallel to the opposite sides 8 and 9 of two successive undulations of the main sheet of the nozzle 1, but are significantly wider than these flanks 8 and 9.

In addition, the free edge 13, 17 of each of the flanks 12, 14 forms at regular intervals a curve 16 whose convexity is outside the stiffener # and which extends into the flank itself in a boss in cone portion. 18 with an axis perpendicular to the crest 15. The boss 18 narrows in the direction of the crest 15 but preferably has its apex 19 in the vicinity of the crests 2,4 of the corrugation of the main sheet.

 The bosses 18 are preferably formed by stamping lvo ca 1 of the sheet folded in V in a matrix of V section. This matrix comprises, in each of its inclined side walls, a lateral notch which widens and deepens in exterior management. The deformation of the sheet which follows the contour of the notches in the matrix causes the bending of the stiffener to be simultaneous, the diameter of which can thus be adapted to that of the main sheet. Fixing members, such as bolt 20 and nut 21 systems, crossing the sidewall 12, 14, between the bosses 18 and the corresponding sidewall 9 or 8, make the stiffener 10 integral with the main plate 1.

The stiffener 10 can, of course, extend over the entire periphery of the nozzle, but preferably it is limited to a length corresponding to the zone in which the bending moments are significant. In most flexible structures, this zone corresponds to two opposite lateral portions and to the upper part of the nozzle. Indeed, as shown in FIG. 4, during the installation of a flexible, curved structure, 1, this structure is subjected during backfilling to lateral thrust forces, illustrated in FIG. 4 by the horizontal arrows fl and f2, which tend to crush the wall laterally towards the interior and, consequently, to push this wall down and especially upwards, as indicated by the dashed line in Figure 4. in this figure that the bending moments are very important midway between points A and D and B and C, while they are zero at points A, B, C and D of the nozzle 1. Consequently the stiffeners 10A and 10B (fig. 5), placed laterally at two opposite points corresponding to the zones where the bending moments are maximum, allow the nozzle to be given sufficient resistance at these points.

 In the same way, the upper part of the nozzle is that which mainly supports the service overloads, such as those transmitted to the roof by the passage of vehicles on the roadway overcoming the flexible structure, in particular in the case where the height of coverage above this volte is weak. To remedy this, a flexible structure according to the invention comprises a row of stiffeners 10C corresponding to this upper part of the nozzle.

The peripheral length of the stiffener 10A, lOB, 10C or the like, depends on the size of the area over which the highest bending moments are exerted.

According to an alternative embodiment, the central corrugation or projection 15 of the stiffener can cover more than two corrugations, three for example or even more.

Of course, the corrugations of the stiffeners 10, like those of the main corrugated plate 1, can have rounded ridges as shown in FIGS. 1 and 2, or have any other shape; for example, these ridges can be flattened.

Whatever the embodiment of the stiffeners, these are arranged in at least one row along the length of the flexible structure. It can be seen that the presence of spaced stiffeners not only makes it possible to reduce the bending stresses in the areas directly capped by the stiffeners, but also in a certain number of adjacent undulations thanks to the transfer of the stresses from one wave to the other, due to the longitudinal continuity of the wall. Stiffeners 10 are therefore spaced along the length of the nozzle and separated by intervals which can vary depending on the importance of the bending moments on this nozzle (FIG. 6).

 Given the peripheral length of these stiffeners, they can be carried by a single corrugated plate or cover several plates, that is to say pass over the junction between two successive plates of the periphery of the structure flexible. In all cases, each stiffener is assembled tightly to the main plate of the flexible structure and forms with it a composite box beam. Such a beam opposes at bending moments a resistance significantly greater than the sum of the resistances of the main corrugated plate and the corrugated plate of the stiffener. It has thus been found that with a stiffener whose depth is double that of the corrugations of the main sheet, the inertia module of the nozzle is multiplied by four. The depth of corrugation of the stiffener can however be slightly less than that; it can for example be 1 1/2 times the corrugation depth of the main sheet. In addition, the stiffener may form a large projection relative to the surface of the nozzle, the waviness depth of the stiffener being able to reach, for example, five or six times the waviness depth of the main sheet. It was thus found that it was possible, thanks to the presence of stiffeners such as those which have just been described, to considerably reduce the thickness of the main sheet 1; for example by using stiffeners having a depth of corrugation double that of the corrugations of the main sheet it has been possible to reduce the thickness of this main sheet by half.

 It is therefore possible to produce, with a sheet having a thickness of 3 1/2 mm, a flexible structure having a diameter of the order of 8 meters, that is to say a flexible structure which, usually, requires a sheet of '' a thickness of 7 mm, which presents a significant saving of material. It is also possible to produce flexible structures with an opening greater than 10 meters with sheets having a thickness of less than 7 mm, which considerably facilitates the production of large flexible structures.

 The realization of the stiffener itself is extremely simple and its assembly is carried out without difficulty.

This stiffener also has a flexibility which allows it to fully match the profile of the main sheet and thus become one with it.

 Such a stiffener can easily adapt to all types of structure. It facilitates the positioning of the nozzle by giving it effective resistance to thrusts due to the backfilling operation. In addition, it participates in the general load-bearing capacity of the structure in service.

Claims (8)

- CLAIMS  1 - Flexible and curved structure, made of corrugated sheet whose corrugations are perpendicular to the generatrices, comprising at least one row of stiffeners spaced from each other in the longitudinal direction of the structure and extending over a portion of the perimeter of the section transverse of this structure, characterized in that each stiffener consists of a bent V-shaped and curved sheet, comprising on either side of a crest (15), projecting from the surface of the structure (1 ) but coaxial with the latter, two sides (12, 14), generally conical and narrow contact with two different undulations of the main sheet, which ccarrport at regular intervals bosses in cone portion (18) projecting towards the exterior and flaring towards the edge of the side flank away from the ridge, fasteners (20, 21) passing through these flanks and those of the main sheet between these projections. 2 - A structure according to claim 1, characterized in that the parts (12, 14) of the stiffener (10) in contact with a corrugation of the main sheet are bent to the same radius and are spaced from each other by a length corresponding exactly to at least one wavelength of this undulation of the main sheet.  3 - flexible bent structure according to one of claims 1 and 2, characterized in that the stiffeners (10) have a depth between 1.5 and 6 times the wavelength of the corrugation of the main sheet.  4 - Curved flexible structure according to one of claims 1 to 3, characterized in that the sheet of the stiffener has substantially the same thickness as the main sheet of the structure (1).  5 - Curved flexible structure according to one of claims 1 to 4, characterized in that the stiffeners (10) are fixed on the convex surface of the structure.  6 - Curved flexible structure according to one of claims 1 to 5, characterized in that it comprises a row of stiffeners (10) in each zone subjected to significant bending moments.  7 - Curved flexible structure according to one of claims 1 to 6, characterized in that it comprises three rows of stiffeners: a row (10C) at its upper part and two lateral rows (10A and 10B) in two diametrically opposite zones . 8 - flexible bent structure according to one of claims 1 to 7, characterized in that the bosses are formed by a local deformation of the sheet which causes simultaneous bending.