FR2654163A1 - Tubular element with a preferred breakage zone and method for fixing it to a support allowing it to be replaced easily and quickly - Google Patents

Abstract

Tubular element including at least one breakage zone (2) having less mechanical strength in the radial direction, whilst not compromising the mechanical strength in the longitudinal direction, characterised in that it is at least partially made from a composite material including at least one layer of fibres (12) wound on either side of the said zone, with a first predetermined angle with respect to the axis (13) of the tubular element and, in the breakage zone (2) with a second predetermined angle with respect to the axis (13), the second angle being greater than the first angle such that the said zone has a weakening of its mechanical strength in the radial direction with respect to the mechanical strength of the element in the axial direction.

Description

 The present invention relates to a tubular element with a privileged rupture zone, its method of attachment to a support allowing its easy and rapid replacement, its application in particular in the field of construction and its manufacturing process.

 In the present description, the term “tubular element” means any hollow cylindrical element of any cross section capable of being carried, moored, embedded, or inserted into a base piece or block acting as a support, this tubular element serving as pole, stake, rod, bar, or even pipe.

 It is known that such tubular elements, in particular when they are used as piles, posts or bars, are sometimes subjected to shocks or brutal and violent forces leading most of the time to their deterioration or to their rupture, which requires their replacement. When they are embedded or embedded in any support, it also happens that one is obliged, to make this replacement, to degrade this support too. This is the case when the mooring, insertion or fixing of the tubular element in or on this support is carried out by cementing, or even concreting.

 In addition, the production of currently known tubular elements which are made of a relatively continuous and homogeneous material does not make it possible to predict, in the event of an impact or a brutal and violent action, the zone where the tubular element will present a defect or its zone breakage, tears or breakage. However, it can be very useful to give the tubular element a privileged break zone.

 Indeed, the presence of such an area can prove to be precious in order to prevent the tubular element from breaking in any place liable to cause injury or cause damage during an impact. Furthermore, if the tubular element breaks in a place provided in advance, its replacement can be facilitated.

 Document EP-A-0 049 726 discloses a tubular element intended for road signs. The preferred break zone is determined by the fact that the tubular element is divided into two parts connected by means of a sleeve whose resistance in the longitudinal direction exceeds that in the transverse direction.

 Such a tubular element is of relatively complex structure which increases the manufacturing price. Furthermore, the system proposed to give the tubular element a privileged break zone is more unattractive.

 In a first of these aspects, the present invention overcomes this drawback by proposing a tubular element comprising at least one rupture zone having less mechanical resistance in the radial direction while not adversely affecting the mechanical resistance in the longitudinal direction, characterized in that it is, at least partially, made of a composite material comprising at least one layer of fibers wound on either side of said zone, with a first predetermined angle relative to the axis of the tubular element, and, in the zone with a second predetermined angle with respect to the axis, the second angle being greater than the first angle, so that said zone exhibits a weakening of its mechanical strength in the radial direction, with respect to the mechanical resistance of the element in the axial direction.

Thanks to these arrangements, the present invention achieves its objective. It will in fact be observed that the fact of increasing the winding angle of the fibers in the preferred rupture zone, has the effect of reducing the mechanical resistance of the tubular element in the radial direction, while not adversely affecting the resistance mechanical
The tubular element in the longitudinal direction. In the event of an impact, the tubular element will therefore break at the privileged rupture zone.

In a preferred embodiment, the winding angle, which is 100 on either side of the rupture zone, progressively passes through the rupture zone from 100 to a maximum of the order of 80 - 850 Ideally, the best performance is obtained with a maximum angle of 900
Furthermore, the fact of producing the tubular element in a composite material with at least one layer of wound fibers has the effect of considerably reducing the cost price of said element, in particular compared to the tubular element of the prior art mentioned more high. Indeed, composite materials based on glass fibers or carbon are less and less expensive.

In addition, the method of manufacturing tubular elements essentially by winding also has the effect of reducing the price.

 The present invention relates, on the other hand, to a means of fixing, mooring, or anchoring a tubular element as succinctly described, this means authorizing the fast and easy anchoring or fixing of the tubular element. so that, in particular in the event of degradation of the latter, its rapid and easy replacement is done without affecting the structure of the support element in which the tubular element is anchored, inserted or fixed.

 These objectives are achieved, according to the invention, by providing in the section of this tubular element intended to be anchored or inserted in the support element, at least one deformable or radially expandable wall element under the action of 'A force exerted by a means acting from the interior of said tubular element to cause this deformable wall element to protrude outside of said tubular element.

 Advantageously, in a preferred embodiment which is particularly simple to implement, the deformable wall element is produced in the form of one or more tongues.

 According to another characteristic of this preferred embodiment, the means intended to exert the force from the interior of the tubular element in the radial direction, towards the exterior, is simply constituted by an enclosure housed inside said element. tubular, of dimensions such that it delimits a volume substantially corresponding to the interior volume of the anchoring segment.

The enclosure is made of a flexible material which can be deformed so that any gas can be introduced from the outside, without any other intervention, resulting in an increase in pressure against said tongues forcing them to move apart and to strongly press on the walls of the well, fixed in the ground and receiving the tubular element, thus opposing an untimely extraction of the tubular element from said well.

Other characteristics and advantages of the invention will emerge more clearly from the description which follows, given with reference to the appended drawings in which
- Figure 1 is a view in axial longitudinal section of a possible embodiment of a tubular element according to 1 invention
- Figure 2 is a schematic elevational view of the element of Figure 1 illustrating an important characteristic of the invention
- Figure 3 is a view similar to Figure 1, on another scale, the tubular member having at its base a possible means for exerting the forces necessary for its fixing or anchoring in a masonry well, Figure 3a schematizing said action.

Referring to these drawings, there is shown, in Figure 1, a tubular element according to the invention, made of a fiber composite material of any known type. This tubular element has three segments (1, 2, 3), the segment 2 forming between the anchoring segment I and the upper segment 3 an annular zone of least resistance called the "rupture zone"
It will then be easily understood that if this tubular element is used as a post, for example as a road sign, the anchoring segment 1 being inserted into the ground or a portion of the roadway 4 and that for some reason a brutal and violent shock exerting a force in the direction of the arrow F affects the aerial portion 3 of this post, the latter, because of the very existence of the breaking zone of weakest resistance will break or break at the level of this segment.

 Figure 2 illustrates an important feature of the invention. Indeed, generally in accordance with the latter, the tubular element is at least partially made of composite materials comprising at least one layer of fibers 12 wound. More precisely, the winding of the fibers is different depending on whether the annular rupture zone 2 or the segments 1 and 3 disposed on either side of the annular zone 2 are considered.

 According to the invention, said layer of fibers is wound on either side of the rupture zone with a first predetermined angle relative to the axis 13 of the tube.

 In the embodiment presently described, the running angle of the fibers is of the order of 100 relative to the axis 13 of the tube in the segments 1 and 3. it is greater than this value (for example 150).

 According to the invention in the rupture zone the fibers are wound with a second predetermined angle relative to the axis of the tube.

 In a preferred embodiment, the winding angle, which is 100 on either side of the rupture zone, progressively passes through the rupture zone from 100 to a maximum of the order of 80 - 850 Ideally, the best performance is obtained with a maximum angle of 900.

 In the embodiment chosen and shown in FIG. 2, two layers of fibers are wound in the opposite direction: a layer of fibers 12 wound from right to left and from bottom to top (relative to FIG. 2) and a second layer wound above the first of fibers 12 'wound from left to right and from bottom to top (relative to FIG. 2). It is observed that the running angle of the fibers 12 or 12 ′ is the same with respect to the axis 13 of the tube. This angle could be significantly different; however in the rupture zone 2 the fibers 12 and 12 'have a running angle which approaches 900 relative to the axis of the tube.

 In this embodiment, the composite material is as follows: Epoxy resin. Type RCA5.

 Thanks to all of these provisions and in particular to the angles of travel of the fibers 12 and 12 ′, the rupture zone 2 has, in transverse direction, a mechanical resistance which is substantially lower than that of the segments 1 and 3 arranged on either side of the area, while not adversely affecting the mechanical strength of the tube in the axial direction.

With a tube having the following characteristics, the following results are expected 1) Characteristic of the tube - length: 2.5 mm - outside diameter: 90 mm - thickness: 2.5 mm - three layers of fiber (3)
1) A layer of fibers parallel to the axis of the tube.

2) A layer with constant winding and less than 150
with respect to the axis of the tube, including, in the area of
rupture.

3) A layer with variable winding from 15 to 850 in the
rupture zone.

- Epoxy resin. Type RCA5.

Anchoring in the ground - 30 cm below ground level (which is zero level) - rupture zone zero level 2) Expected result = - Rupture at the level of the rupture zone in the event of a shock in an impact located one meter above the ground, corresponding to an impact of a mass of 50 Kg, launched horizontally at 26 km / h.

 In the event of damage to a post and rupture of the latter, especially if it is a road sign, it should be considered for replacement.

 Currently, the part of the post in the ground (in this case, segment 1, Figure 1) is anchored in the latter by sealing with mortar or cement, so that the operation of replacing the pole implies an attack of the whole on the ground, which represents the contribution of specialized tools, the repair of a well, resealing with cement or by concreting, etc.

 The aspect of the invention presently described aims to propose a means of fixing a tubular element such that its replacement is easy and does not require an attack on the whole of the ground as explained above, in the event that the tubular element is implanted in the ground.

 In general, in accordance with this aspect of the invention, the anchoring segment comprises at least one deformable or radially extendable wall element, under the action of a force exerted by a means acting from the inside the tubular element.

 In the embodiment chosen and shown, the deformable or extensible wall element is in the form of one or more tabs 5 obtained by producing in the anchoring segment 1 a plurality of longitudinal grooves 6. These tongues are capable of being pushed outwards under the action of a force exerted from inside the tubular element by any suitable means.

 Thus if one decides to implant the tubular element in the ground it sufffit to make in the latter a well 4a of diameter equal to or slightly greater than the external diameter of the tubular element and then, after having introduced the post in the well 4a, to act on the tongues 5 so that the latter are biased towards the outside (arrows f, FIG. 3a), and bear on the internal wall of the well 4a. Therefore the tubular element (or the post constituted by this tubular element) is securely held in the anchoring position as long as a force is exerted on the tongues in the direction of the arrows f.

 On the other hand, when it is desired to remove the post, to replace it or as a result of damage to the latter, it suffices to cancel the force f so that the tubular element, or more precisely its anchoring segment can easily slide inside the well.

 Any mechanical means controlled in an appropriate manner can be used to exert the abovementioned stress on the tongues 5. However, according to a preferred embodiment, there is provided for this purpose an enclosure 9 with flexible and deformable walls which is housed at the inside the anchoring segment 1 of said tubular element, this enclosure being capable of being supplied with a gas such as air, or with a fluid such as oil, admitted by a pipe 7 and an orifice 8 as compressed air, or pressurized fluid. In this embodiment, the enclosure 9 is an element of the bladder type comprising on its external walls zones 10 of greater resistance to stress and intended to guarantee a radial deformation of the bladder applied to the tongues or tongues 5 to which they face each other, so as to solicit the latter more effectively.

 it suffices, when the desired action is obtained and the anchoring intensity achieved, to maintain the pressure inside said bladder during the entire period during which the post must remain in place where no damage has been suffered.

 But if, for any reason, we wanted to remove this post or if it were to be accidented, that is to say "sheared" in the area of zone 2, by virtue of its constitution, it will suffice to extract the anchored part 1 whose tongues or tongues 5 are no longer pressed against the internal wall of the well 4a due to the sudden fall (accidental or controlled) of the air pressure within the balloon. This extraction operation can be done as simply and as quickly as possible without damaging in any way the structure of the well 4a, no material of the cement, concrete or other type having been used to ensure the anchor of the post.

 One thus realizes all the interest which the invention brings, as well as regards the structure of the post which comprises an annular zone of weakening as with regard to its mode of anchoring in an element- support. We also realize the multiple possibilities of application of the invention, as well in the field of road signs as in the field of building and public works from the moment a post, a pile, a tube, a bars, are intended to be anchored in a ground or in a wall and are exposed to risks of rupture or damage requiring rapid or even immediate replacement.

 The invention meets these needs and in a way that requires no degradation of the "support", the minimum of means of implementation for installation and removal, with maximum simplicity, presiding over this installation and this removal.

 Of course, any composite material constituting the tubular element meeting, on the one hand, the condition of rupture imposed in a determined sector of this element and on the other hand the specifications which this element must meet, may be used.

 Similarly, any tubular element meeting these requirements may include, on or in the section intended to be anchored, any suitable means for urging the walls of this section outward to constitute, in accordance with the invention, the means of anchoring proper within a well made in the support element for which this tubular element is intended.

 it goes without saying that the present invention has been described for purely explanatory and in no way limitative and that any modification may be made without departing from its scope.

Claims (10)

 1. Tubular element comprising at least one rupture zone (2) having less mechanical resistance in the radial direction while not adversely affecting the mechanical resistance in the longitudinal direction characterized in that it is, at least partially, made of a composite material comprising at least one layer of fibers (12) wound on either side of said zone, with a first predetermined angle with respect to the axis (13) of the tubular element, and, in the zone of rupture (2), with a second predetermined angle relative to the axis (13), the second angle being greater than the first angle, so that said zone exhibits a weakening of its mechanical strength in the radial direction, by in relation to the mechanical resistance of the element in the axial direction.  2. Tubular element according to claim 1, characterized in that said first angle is less than or equal to 150 and, preferably, equal to 100.  3. Tubular element according to any one of claims 1, 2, characterized in that said second angle has a variable value between that of the first angle and a maximum value  4. Tubular element according to claim 3, characterized in that the maximum value is of the order of 850  5. Tubular element according to claim 3, characterized in that the maximum value is of the order of 900  6. Tubular element according to any one of claims 1 to 5, comprising a segment on either side of the zone, characterized in that one of the segments (1 or 3), located on either side of the annular zone of least resistance (2), is intended for its anchoring in a support element (4).  7. Tubular element according to any one of claims 1 to 6, characterized in that it comprises, in the vicinity of the rupture zone, an anchoring segment comprising a deformable or radially extendable wall element (5 ) under the action of a force (f) exerted by a means acting from the interior of said tubular element to cause this deformable wall element to protrude outside the tubular element.  8. Tubular element according to claim 7, characterized in that the deformable wall element is in the form of tongues (5) cut in the wall of the anchoring segment of the tubular element.  9. Tubular element according to any one of claims 7,8, characterized in that it comprises, inside the segment intended for anchoring (1), an inflatable enclosure (9) intended to act on said means of deformable wall (5) for carrying out the actual anchoring.  10. Application of a tubular element according to any one of claims 1 to 9 to the production of posts or piles in the field of construction in particular.