FR3092596A1 - System and method for securing against the impact of objects - Google Patents

Abstract

System and method for securing against the impact of objects Security system against the impact of objects, comprising a net (3) intended to retain objects, a support (4) on which the net (3) is mounted, and a retaining means (5) of the support (4) ) in a reference position (R), the holding means (5) comprising a holding device (15, 16) fixed to the ground (11) and a holding element (17, 18) connecting the holding device (15 , 16) to the support (4), and a retaining means (23) of the support (4) provided with a retaining device (24, 25) fixed to the ground (11) and a retaining element (26, 27) connecting the retainer (24, 25) to the retainer (5), the retainer (24, 25) having a greater tear resistance than the retainer (15, 16). Figure for the abstract: f igure 1

Description

System and method for securing against the impact of objects

The invention relates to systems and methods for securing against the impact of objects, in particular falling stones, trees or similar elements, and more particularly the anchoring of such systems.

Generally, systems for securing against the impact of objects consist of mainly metallic constructions, with beams supporting nets and retained by guy wires connected to anchors. These systems are bulky and difficult to assemble. They must also be sufficiently robust and effective, especially after being installed and during the entire period of waiting for an object impact. In addition, these constructions include anchors in the ground or in the rock, made up of metal bars whose length sealed in the ground must have a resistance to tearing corresponding to the energy to be dissipated at the time of the future impact in the net. . Metal bars are made of ductile, medium-strength steel, or higher-strength treated steel. However, these treated steel bars are susceptible to corrosion when they are subjected to a bending force, even low, corresponding to the tension in the stay cables when the system is assembled, or during the waiting phase before impact. . The stress corrosion process can lead to bar failure very quickly, even in the absence of impact loading.

Mention may be made, for example, of French patent application FR2953228 which discloses a rockfall screen comprising a post anchored to a rock wall at one end and having a head connected to the rock wall upstream of the screen by guys anchored in the rock. In addition, the screen comprises an edge cable anchored in the rock wall on either side of the screen and mounted to slide axially on the post, and a net held by an edge to the edge cable. The edge cable is configured to stretch when an edge cable tension exceeds a threshold. The screen also has a fusible cable passing downstream of the post and fixed to the edge cable, the fusible cable replacing the edge cable to hold the net and is configured to lengthen under a low tension compared to the sill. But in the event of a fall of very heavy rocks, the retaining net deforms and the post tends to bend, tearing off the guys and the edge cable.

Object of the invention

An object of the invention consists in overcoming these drawbacks, and more particularly in providing means for improving the safety of open-air sites where there is a risk of impact from objects, in particular rockslides or trees or similar items.

According to one aspect of the invention, there is proposed a system for securing against the impact of objects, comprising a net intended to retain objects, a support on which the net is mounted, and a means for holding the support in a reference position, the holding means comprising a holding device fixed to the ground and a holding element connecting the holding device to the support.

The system further comprises a support retaining means, provided with a retaining device fixed to the ground and a retaining element connecting the retaining device to the retaining means. In particular, the retaining device has a greater tear resistance than the holding device.

Thus, a system is offered which makes it possible to improve the safety of the systems against the impact of objects using a net. More specifically, a dual anchoring system is offered using a holding device and a retaining device, intended to withstand the impacts of different objects, in particular objects having different masses. The holding device is configured to hold the support in a reference position in the waiting phase, that is to say before the impact of an object. The holding device resists the stresses exerted by the support, due to the weight of the net and the support, to maintain the support in the reference position, also denoted operating position. More particularly, the retaining device will be stressed to retain objects of low mass, while the retaining device will be stressed to resist objects of higher mass. The retaining device is particularly configured to resist the tearing of the support during the impact of an object, for example a flying object (carried by the wind), or rolling (such as a mobile vehicle or automobile), or flowing (such as a mudslide), including falling rocks, trees or the like. The retainer provides most of the securing as it prevents the stand and the net from falling while lying on the ground upon impact with an object.

The retainer may be configured to exert a tension on the retainer of less than or equal to 10 N, preferably less than 1 N, when the bracket is in the reference position.

Thus, the securing system makes it possible to avoid excessive stressing of the retaining device when the support is in a reference position (that is to say in the phase of waiting for an impact from a possible object ). In this case, the retaining device is little stressed in tension when the support occupies its reference position. Thus, deterioration of the retaining device by stress corrosion is avoided. Advantageously, the retaining device retains its integrity over time and retains its ability to resist tearing since it will only be stressed at the time of the impact of an object applying a tension on the upper retaining element. to the pull-out resistance of the holding device.

According to one embodiment, the holding element is a first cable and the retaining element is a second cable connected to the holding device.

According to another embodiment, the holding element is a first cable and the retaining element is a second cable connected to the first cable.

For example, the holding element and the retaining element form a single cable connecting the support, the holding device and the retaining device to each other.

The holding device and the retaining device may comprise respectively first and second elongated elements intended to be introduced into the ground, the second elongated element having a length greater than that of the first elongated element.

Each elongated element may comprise an elongated body provided with several protrusions intended to penetrate into the ground.

The net can be mounted on the support in an extended fashion and the holding device and the retaining device are located upstream of the net.

According to another aspect, there is proposed a method of securing against the impact of objects, in which, a net intended to retain objects is mounted on a support, the support is maintained in a reference position using 'a holding means provided with a holding device fixed to the ground and the holding device is connected to the support.

The method includes fixing to the ground a retaining device having a pull-out strength greater than that of the retaining device, and connecting the retaining device to the retaining means.

It is also possible to connect the retaining device to the retaining means by a retaining element which exerts a tension on the retaining device less than or equal to 10 N, preferably less than or equal to 1 N, when the support occupies the reference position. .

Brief description of the drawings

Other advantages and characteristics will emerge more clearly from the following description of particular embodiments and implementations of the invention given by way of non-limiting examples and represented in the appended drawings, in which:

: FIG. 1 schematically illustrates a front view of an embodiment of a system for securing against the impact of objects;

FIG. 2 schematically illustrates a side view of another embodiment of a system for securing against the impact of objects;

FIG. 3 schematically illustrates a side view of yet another embodiment of a system for securing against the impact of objects; and

: Figure 4 schematically illustrates a side view of the system of Figure 1 in case of impact of objects.

In Figures 1 to 4, there is shown a securing system 1 against the impact of objects 2. In particular, the system 1 is designed for securing against the fall of rocks 2, stones, trees or similar items. The system 1 is also suitable for retaining objects in motion, such as for example a mobile rolling vehicle or motor vehicle, a flying object (carried by the wind), or a flowing object (such as a mudslide). In addition, the system 1 comprises a net 3 intended to retain these objects 2. The system 1 further comprises a support 4 and a means 5 for holding the support 4 in a reference position R. The net 3 preferably comprises a 6 mesh of steel strands. The net 3 is mounted fixed or removable on the support 4. For example, the net 3 is mounted on four attachment points 7 to 10, two upper attachment points 7, 8 located at an upper end of the support 4, c 'that is to say away from the ground 11, and two lower attachment points 9, 10 located at a lower end of the support 4, that is to say closer to the ground 11. The reference position R corresponds to a position in which the support 4 is upright and the net 3 can be deployed to resist the impact of an object 2, for example to prevent the fall of a rock 2. The support 4 occupies its reference position R by being standing on the ground 11, the ground 11 being able to be horizontal or inclined. When the support 4 is upright, it can be perpendicular to the ground 11, or be inclined at an angle, relative to the ground, of between 45° and 135°. For example, the support 4 can comprise two masts 12, 13 on which the net 3 is mounted. A first mast 12 comprises an upper attachment point 7 and a lower attachment point 10. The second mast 13 comprises the upper 8 and lower 9 attachment points. The masts 12, 13 can be anchored in the ground 11, or resting on the ground 11. A mast 12, 13 generally has an elongated shape. A mast 12, 13 can be a cylinder, for example a solid cylinder with a circular section, or a tube, or a bar, solid or hollow. By cylinder, we mean a solid bounded by a cylindrical surface generated by a set of parallel straight lines, denoted generators, resting on a closed plane curve, denoted directrix, and two planes intersecting the generatrices. Each mast 12, 13 may have a base 14 to rest against the ground 11. In addition, each mast 12, 13 may have a specific anchoring system, not shown for simplification purposes, to anchor the mast 12, 13 deep in the ground 11. When the support 4 occupies its reference position R, illustrated in Figures 1 to 3, the net 3 occupies a deployed position to retain objects 2. In other words, the net 3 is stretched by the support 4. When the support 4 comprises two masts 12, 13, the net 3 is attached to the masts 12, 13 so as to be deployed between the two masts 12, 13.

Furthermore, the holding means 5 makes it possible to hold the support 4 in its reference position R. In general, the holding means 5 comprises at least one holding device 15, 16 and at least one holding element 17, 18 A holding device 15, 16 is configured to hold the support 4 in its reference position R. In particular, each holding device 15, 16 is fixed to the ground 13 and each holding element 17, 18 connects a holding device 15, 16 to the support 4. In other words, each holding device 15, 16 is associated with a holding element 17, 18 attached to the support 4 and to the holding device 15, 16 with which it is associated. The holding elements 17, 18 can be cables, for example steel cables. A first holding element 17 is fixed, on the one hand to a first holding device 15, via a first ring 19 fixed to the first anchoring device 15, and on the other hand to the support 4, for example to the first mast 12 , via a second ring 20 fixed to the support 4. To balance the support 4, the holding means 5 may further comprise a second holding device 16 fixed to the ground 11 and a second holding element 18 connecting the second holding device 16 to the support 4. The two holding devices 15, 16 cooperate to hold the support 4 in its reference position R. The second holding element 18 is fixed, on the one hand to the second holding device 16, via a third ring 21 fixed to the second holding device 16, and on the other hand to the support 4, for example to the second mast 13, via a fourth ring 22 fixed to the support 4. The holding devices 15, 16 each have a resistance to tearing, that is to say that the devices holding devices 15, 16 remain in position as long as a voltage applied to the holding devices 15, 16 is lower than a holding threshold voltage. When a voltage applied to a holding device 15, 16 exceeds the holding threshold voltage, then the holding device 15, 16 is torn from the ground 11 and no longer holds the support 4 in its reference position R, as illustrated in figure 4. In this case, the support 4 changes position with respect to its reference position R. That is to say, the support 4 can occupy an inclined position D of an angle A with respect to its reference position, as shown in Figure 4.

More particularly, the system 1 comprises a retaining means 23 configured to retain the support 4 in the event of impact from objects 2. Generally, the retaining means 23 comprises at least one retaining device 24, 25 and at least a retaining element 26, 27. A retaining device 24, 25 is configured to retain the support 4 in an inclined position D, illustrated in FIG. 4. The inclined position D corresponds to a position in which the support 4 is inclined d 'an angle A with respect to its reference position R. That is to say that the retaining device 24, 25 is configured to prevent the support 4 from lying on the ground 11. In particular, each retaining device 24, 25 is fixed to the ground 11 and each retaining element 26, 27 connects a retaining device 24, 25 to the retaining means 5. In other words, each retaining device 24, 25 is associated with a retaining element 26, 27 attached to the holding means 5 and to the retaining device 24, 25 to which it is t associated. The retaining elements 26, 27 can be cables, for example steel cables.

In Figure 1, there is shown an embodiment in which each retaining element 26, 27 is connected to a holding device 15, 16. A first retaining element 26 is fixed, on the one hand on the first holding 15, via the first ring 19, and on the other hand to a first retaining device 24, via a fifth ring 28 fixed to the first retaining device 24. To balance the support 4, the retaining means 23 can further comprise a second retaining device 25 fixed to the ground 11 and a second retaining element 27 connecting the second retaining device 25 to the second retaining device 16. The two retaining devices 24, 25 cooperate to maintain the support 4 in its inclined position D in the event of tearing of the retaining devices 15, 16. The second retaining element 27 is fixed, on the one hand to the second retaining device 16, via the third ring 21, and on the other hand to the second retaining device 25, via a sixth ring 29 fixed to the second retaining device 25. The retaining devices 24, 25 each have a resistance to tearing, in particular, the retaining devices 24, 25 remain in position as long as a tension applied to the retaining devices restraint 24, 25 is less than a tear-off threshold voltage. When a voltage applied to a retaining device 24, 25 exceeds its tearing threshold voltage, then the retaining device 24, 25 is torn from the ground 11 and no longer maintains the support 4 in its inclined position D. In this case , the support 4 falls while lying on the ground 11, and the system 1 no longer performs its security function. More particularly, each retainer 24, 25 has a higher pull-out resistance than each of the retainers 15, 16. In other words, the threshold pull-out voltage of the retainers 24, 25 is higher than the holding threshold voltage of the holding devices 15, 16.

Thus, when a retaining device 15, 16 is torn off, the support 4 tilts and is retained in its inclined position D by the retaining means 23, because the retaining means 23 is connected to the support 4, by the intermediary of the holding means 5. In particular, in the inclined position D, illustrated in FIG. 4, the support 4 is held upright relative to the ground 11 and the net 3 can retain the object 2 which has struck it . In addition, in the inclined position D, the support 4 has not collapsed and has not laid on the ground 11. In the case where the ground 11 is horizontal, the retaining means 23 cooperates with the means of holding 5 to provide a securing system 1 which can absorb the shock due to the impact of an object 2. In other words, during an impact of an object 2 on the net 3, the holding means 5 can be torn off before the retaining means 23. The retaining means 5 will then have absorbed part of the shock created by the impact of the object 2. Furthermore, when the ground 11 is inclined, the securing system 1 allows also to absorb the shock, and in addition the holding means 5 retains the support 4 in its reference position R, by undergoing a tension due to the weight of the support 4 and the net 3.

According to another embodiment, illustrated in Figure 2, the holding 17 and retaining 26 elements are two cables connected together by a ligature 30.

According to yet another embodiment, illustrated in FIG. 3, the holding 17 and retaining 26 elements form a single cable 31 connecting the support 4 with a holding device 15 and a retaining device 16. More particularly, the cable 31 is connected to the holding device 15 by a fastening means 32, such as loops, eyelets, or ligatures.

In FIG. 4, the impact of an object 2 on the security system 1 has been shown. A case has also been shown where the ground 11 is inclined. Preferably, the holding 15, 16 and retaining 24, 25 devices are located upstream of the thread 3. In particular, when an object 2 strikes the thread 3, it causes an increase in the tension applied to the holding devices 15, 16. The impact of the object 2 tends to tilt the support 4 towards its inclined position D. When a voltage applied to the holding devices 15, 16 exceeds the holding threshold voltage and remains below the threshold voltage d tearing of the retaining devices 24, 25, then the retaining devices 15, 16 are torn off, the support 4 tilts into its inclined position D, and the retaining devices 24, 25 on which the tension is applied are not torn from the ground 11. In this case, the retaining devices 24, 25 retain the support 4 in its inclined position D. There is shown in Figure 3, the first retaining device 15 in the situation where it is torn partly from the ground 11 It is flexed due to a t important tension applied to him.

Furthermore, when the support 4 occupies its reference position R, first tensions T1, T2 are exerted by the support 4 respectively on the first and second holding devices 15, 16. In addition, second tensions T3, T4 are exerted by the retaining elements 26, 27 on the first and second retaining devices 24, 25 respectively. Advantageously, the retaining 5 and retaining 23 means are configured so that, when the support 4 occupies its reference position R, the second voltages T3, T4 are strictly lower than the first voltages T1, T2. For example, the support 4 is placed so that the holding elements 15, 16 are taut and the retaining elements 26, 27 are preferably loose. In this case the second voltages T3, T4 are respectively lower than the first voltages T1, T2. For example, when the retaining elements 26, 27 are placed on the ground 11, the second voltages T3, T4 are negligible. More particularly, a retaining element 26, 27 is configured to exert a second tension T3, T4 on the retaining device 24, 25, to which it is connected, which is less than or equal to 10 N, preferably less than or equal to 1 N. In fact, when the second tensions T3, T4 are less than 10 N, it is considered that the retaining device 24, 25 is under little stress in tension and the phenomenon of stress corrosion of the retaining devices 24, 25 is avoided. When the second tensions T3, T4 are less than 1 N, it is considered that they are negligible, that is to say that they do not lead to stress corrosion of the retaining devices 24, 25. stress of the retainers 24, 25 occurs when they are subjected to stresses, in particular stresses greater than 10 N.

In other words, the retaining elements 26, 27 are configured so that, when the support 4 occupies its reference position R, the retaining means 23 is little or not stressed in tension. For example the retaining means 26, 27 are placed on the ground and the second voltage T3, T4 is low. For example, one could choose a retaining element 26, 27 whose weight is less than 10 N, preferably less than 1 N. Advantageously, when the retaining means 23 is little or not stressed in tension, it retains its capacity to pull-out resistance. This avoids stressing the retaining means 23 in tension in an operating situation when the support 4 is in its reference position R and there is no object 2 pressing against the net 3. In addition, the means 23 will only be stressed when a tension exerted on the retaining means 23 exceeds the holding voltage threshold of the holding means 5.

The retainers 15, 16 and retainers 24, 25 may include elongated members 40-43, respectively. Each elongated member 40-43 is configured to penetrate soil 11. of a sealant. For example, the elongated elements 40 to 43 are rods. The rods can be made of steel. As a variant, the elongated elements 40 to 43 can be fixed to the same retaining piece, such as a concrete block. According to another variant, the elongated elements 40 to 43 can be fixed respectively to separate retaining pieces from each other. Preferably the rods are hollow. More particularly, the elongated elements 42, 43 of the retaining devices 24, 25 each have a greater length than those of the elongated elements 40, 41 of the retaining devices 15, 16. Thus, the pull-out resistance of the retaining devices 24 , 25 is greater than those of the holding devices 15, 16. In general, each elongated element 40 to 43 has a body. Advantageously, each body of the elongated elements 40 to 43 is provided with protuberances 44 intended to increase the coefficient of resistance to tearing. For example, the elongated elements 40 to 43 are threaded rods, that is to say comprising a helical thread, or comprising several parallel threads between them.

The system 1 which has just been described can be installed using a method of securing against the impact of objects 2, in which the net 3 intended to retain objects 2 is mounted on the support 4. , the support 4 is held in its reference position R using the holding means 5 provided with a holding device 15, 16 fixed to the ground and the holding device 15, 16 is connected to the support 4. , a retaining device 24, 25 having a resistance to tearing greater than that of the retaining device 15, 16 is fixed to the ground, and the retaining device 24, 25 is connected to the retaining means 5.

The invention which has just been described is easy to assemble and provides effective protection against the impact of objects. The securing system and method make it possible to provide a double anchorage to hold a protective device against the impact of objects, which makes it possible to avoid placing the restraint devices under excessive stress during the waiting phase of a possible impact, so that the double anchor retains its integrity over time and maintains its resistance.

Claims (10)

System for securing against the impact of objects, comprising a net (3) intended to retain objects (2), a support (4) on which the net (3) is mounted, and a retaining means (5) of the support (4) in a reference position (R), the retaining means (5) comprising a retaining device (15, 16) fixed to the ground (11) and a retaining element (17, 18) connecting the retaining device holding (15, 16) to the support (4), characterized in that it comprises a retaining means (23) of the support (4), provided with a retaining device (24, 25) fixed to the ground (11) and a retainer (26, 27) connecting the retainer (24, 25) to the retainer means (5), and in that the retainer (24, 25) has a pull-out resistance greater than that of the retaining device (15, 16). A system according to claim 1, wherein the retainer (26, 27) is configured to exert a tension (T3, T4) on the retainer (24, 25) less than or equal to 10 N, preferably less than or equal to 1 N, when the support (4) occupies the reference position (R). A system according to claim 1 or 2, wherein the retainer (17, 18) is a first cable and the retainer (26, 27) is a second cable connected to the retainer (15, 16). System according to one of claims 1 to 3, in which the retaining element (17, 18) is a first cable and the retaining element (26, 27) is a second cable connected to the first cable (17, 18 ). System according to one of claims 1 to 3, in which the retaining element (17, 18) and the retaining element (26, 27) form a single cable (31) connecting the support (4), the device holder (15, 16) and the retainer (24, 25) between them. System according to one of claims 1 to 5, wherein the retaining device (15, 16) and the retaining device (24, 25) respectively comprise first (40, 41) and second (42, 43) elongated elements intended to be introduced into the ground (11), the second elongate element (42, 43) having a length greater than that of the first elongate element (40, 41). A system according to claim 6, wherein each elongate member (40-43) has an elongate body provided with a plurality of protrusions (44) for penetrating the ground (11). System according to one of claims 1 to 7, in which the net (3) is mounted on the support (4) in an extended manner and the holder (15, 16) and the holder (24, 25) ) are located upstream of the net (3). Method of securing against the impact of objects, in which, a net (3) intended to retain objects (2) is mounted on a support (4), the support (4) is maintained in a reference position (R ) using a holding means (5) provided with a holding device (15, 16) fixed to the ground (11) and the holding device (15, 16) is connected to the support (4), characterized in that it comprises an attachment to the ground (11) of a retainer (24, 25) having a resistance to tearing greater than that of the retainer (15, 16), and the device is connected retaining (24, 25) by retaining means (5). Method according to Claim 9, in which the retaining device (24, 25) is connected to the retaining means (5) by a retaining element (26, 27) which exerts a tension (T3, T4) on the retaining device (24, 25) less than or equal to 10 N, preferably less than or equal to 1 N, when the support (4) occupies the reference position (R)