FR2698896A1 - Device to prevent oscillation of tall structures - has inert mass attached to structure by elastic components and shock-absorbing cable springs which can be regulated - Google Patents

Abstract

The device consists of an inert mass (2) attached to the structure (1) by elastic components and shock-absorbers (5) which consist of U-shaped steel cables. The cable springs and the attachment (6, 7) with which they are fixed to the structure and/or the inert mass can be regulated. The curved part (10) of the U is adjustable so that elasticity and the amount of shock absorption can be regulated continuously. USE/ADVANTAGE - For preventing oscillation of tall structures such as chimneys an, pylons. Device can be simply adapted to elasticity and shock-absorption of the structure.

Description

 Device for attenuating the oscillations of works or structures, in particular of slender works such as chimneys, pylons, masts and similar works.

 The present invention relates to a device for attenuating the oscillations of structures or structures, in particular of slender structures such as chimneys, pylons, masts and the like, comprising an inert mass connected to the structure by elastic and damping elements. .

 lt is well known that slender structures such as chimneys, pylons, masts and similar structures tend to oscillate under the effect of wind or earthquakes. The extent of these oscillations depends in particular on the degree of proper damping of the structure, which depends in particular on the configuration and the material of the structure. For example, metal chimneys are much more subject to oscillations than concrete chimneys.

 To mitigate these oscillations, a variety of devices have already been proposed, generally provided at the head of structures, inter alia devices comprising a suspended inert mass, the oscillating movements of which are damped by damping elements of the damping type for motor vehicles. A simpler and more effective solution is proposed in document DE-A-28 06 757, according to which elements which are both elastic and dampers are arranged radially between the inert mass and the structure. These elastic and damping elements are constituted by wired helical springs, that is to say constituted by a steel cable which, during its deformation, dissipates energy by the friction of the strands of the cable one on the other. other.

 This known device for attenuating oscillations has the drawback of not allowing a simple optimal adaptation of the elasticity and damping properties of the connection between the inert mass and the structure, an adaptation which would however be desirable in order to be able to take account both the importance of the inert mass, the characteristics of the structure, the evolution of these characteristics over time (for example corrosion in the case of metallic structures), the actual characteristics of the foundation soil , etc ...

The only possibilities provided for this purpose consist either in the choice of a greater or lesser number of elastic and damping elements, or in the incorporation into the elements of damping materials, for example rubber or plastic, and / or in the coating of the elements using such materials. Such adaptation is neither simple nor continuous.

 The present invention relates to a device for attenuating the oscillations of structures, a device which allows, by simple means, an optimal adaptation of its elasticity and damping characteristics to the inert mass and to the structure.

 The subject of the invention is a device for attenuating the oscillations of structures, in particular of slender structures such as chimneys, pylons, masts and similar structures, comprising an inert mass connected to the structure by elastic and damping elements constituted by one or more wired springs. According to the invention, the wired spring or springs and their mode of connection with the structure and / or with the inert mass are designed so that the elasticity effect and the damping effect of the wired springs are adjustable.

 Preferably, the wired springs and their mode of connection with the structure and / or with the inert mass are designed so that the elasticity effect and the damping effect of the wired springs are continuously adjustable.

 The adjustment of the elasticity effect and the damping effect of the wired springs can advantageously be carried out by the fact that the useful length of the wired springs between their points of connection with the structure and with the inert mass is adjustable .

 According to one embodiment, the cabled springs can each be in the form of a section of U-shaped steel cable, connected in an adjustable manner to the inert mass on the one hand, and to the structure, on the other hand starts with the two arms of the U so that the length of the curved working part of the spring between the attachment points of the two arms of the U is adjustable.

 In order to obtain a high damping effect with a small number of elastic and damping elements, it is possible to produce each of the springs wired by a cable section in the form of a loop with two U's, the branches of which are connected to the inert mass, on the one hand, and to the structure, on the other hand, respectively by two spaced adjustable fixing points so as to allow an adjustment of the length of the two opposite curved useful parts of the section of steel cord between the structure and the inertia mass.

 Such an adjustment can be obtained, either by spacing and bringing one of the two ends of the wired spring section bent in the form of a loop, with displacement of the cable relative to its fixing devices which can then be immobile with respect to the inert mass and with respect to the structure. However, the same result can also be obtained by the fact that at least one of the two devices for fixing to the inert mass, on the one hand, and to the structure, on the other hand, is adjustable in position relative to to its support (inert mass, structure).

 According to another embodiment, a single elastic and shock-absorbing element is provided for the inert mass, this element comprising a single section of steel cord shaped as a coil spring passing through the holes of four rings, two of which are connected to the inert mass and two at work, at least one of each of these two rings being adjustable in position along its axis.

Referring to the accompanying schematic drawings, several illustrative and non-limiting embodiments of an oscillation attenuation device according to the invention will be described below. on the drawings
Figure 1 is a vertical section, in a diametral plane, of a device according to the invention installed in a mast;
Figure 2 is a top view of the device of Figure 1;
Figure 3 is a vertical section, in a diametral plane, of a device according to the invention installed on a chimney;
Figure 4 is a top view of the device of Figure 3;
Figure 5 is a vertical section in a diametrical plane of a device according to the invention comprising a single elastic and damping element and installed in a mast;
FIG. 6 is a top view of the device of FIG. 5.

 The device according to the invention as illustrated in Figures 1 and 2 is intended to attenuate the oscillations of a slender structure 1 such as a mast, for example a metal mast. This device comprises an inert mass 2 suspended pendulumly at the upper end of the mast 1, inside the latter, for example by a cable 3 hooked to a crosspiece 4 fixed inside the mast 1.

 The importance of the inert mass 2 is chosen, in a manner known per se, as a function of the total mass of the structure 1. This method of determination is known per se and does not come within the scope of the present invention.

 The mass 2 is also connected radially to the mast 1 which surrounds it by several elastic elements and shock absorbers 5. In the example shown, the elements 5 are three in number and are distributed 1200 from each other around the mass inert, as shown in Figure 2.

 Each element 5 is constituted by a section of steel cable shaped like a U-shaped stirrup by its blocking in two clamping devices 6 and 7 fixed one internally to the mast 1, and the other to the inert mass 2. The element 5 thus has two branches 8 and 9 held in the clamping devices 6 and 7 and a curved part 10 connecting the two branches 8 and 9 together and constituting the useful part of element 5. The two clamping devices 6 and 7 which can be for example screw clamping devices similar to screw booms used for electrical connections allow, when they are loose, to slide the element 5 up or down, thus to vary the length of the useful part 10 of the element between the two clamping devices 6 and 7. This variation in the useful length of the elements 5 causes a variation in the stiffness and the damping effect of the elements 5, cushioning effect ement being produced by the friction between the strands of the steel cable during the deformations which the useful part 10 of the elements undergoes under the action of oscillations induced in the structure 1, for example by the dynamic effect of the wind .

 According to the embodiment of Figures 3 and 4, a structure 1 1 constituted for example by a metal chimney comprises, at its upper end, for the damping of its oscillations, an inert annular mass 12 surrounding the end at a distance upper part of the chimney 11 by being suspended for example by three cables 13 with three arms 14 fixed in a cantilever, in a radial position, externally on the chimney 11.

 Several elastic and damping elements 15 are arranged between the chimney 11 and the mass 12, these elements being, in the example shown, three in number and offset by 120 relative to each other around the chimney 11. Each element 15 consists of a section of steel cable shaped as a loop by passing through two clamping devices 16 arranged on the inside of the ring 12, one above the other, and through two clamping devices 17 arranged on the external face of the chimney 11, one above the other in such a way that the two ends 18, 19 of the cable section are located between the two clamping devices 17. As a result, the section of cable constituting each element 15 comprises two curved parts 20 constituting two useful parts with elastic effect and damping, situated respectively between the two upper devices 16 and 17 and the two devices 16 e t 17 lower.

 By variation of the length of said useful parts 20, this variation can be done either by spacing the two ends 18 and 19 from each other, the devices 16 and / or 17 remaining stationary, or, when at least one of the devices 16 or devices 17 is connected to the ground 12 or to the chimney 1 1 in a vertically movable manner, by displacement of the devices 16 and 17 in the direction of the spacing or reciprocal bringing together of the two devices 16 and / or of the two devices 17, it is possible to adjust the elasticity and damping effect of the elements 15.

 In the embodiment according to FIGS. 5 and 6 in which a mast 21 is fitted at its upper end with an inert mass 21 suspended by a cable 23 pendulumly to a crosspiece 24 inside the mast, an element 25 forming a spring and damper, consisting of a single section of very long steel cable, is disposed between the mast 21 and the mass 22.

 To this end, two rings 26 each comprising a multitude of regularly distributed holes around its periphery are connected to the mast 21 by being arranged one above the other, and two rings 27 also each comprising a multitude of distributed axial holes on its periphery are connected to the mass 22 by being arranged one above the other. At the location of each axial hole, each outer ring 26 may include a cable tightening device, for example a screw engaged in a tapped hole opening into the axial hole. Furthermore, at least one of the outer rings 26 may be connected to the mast 21 and or at least one of the inner rings 27 can be connected to the mass 22 with mobility in the vertical direction, which allows the two outer rings to be brought closer and apart 26 and / or the two inner rings 27.

 The element 25 consisting of a single section of steel cable is threaded helically into the axial holes of the rings 26, 27 so as to constitute, over the entire periphery of the mass 22, a multitude of substantially radial loops, elongated vertically . Thus, the approximation or spacing of the two rings 16 and / or the two rings 17 makes it possible to shorten or lengthen the vertical branches 28, 29 of the loops of the element 25 and, consequently, to increase or reduce consequently the length of the curved useful parts 30 situated outside the rings 26 and 27. This therefore makes it possible to vary both the elasticity and the damping effect of the useful parts 30 of the elastic element 25 and damper.

 It should be noted that the embodiments shown and described have been given only by way of illustrative and non-limiting examples and that numerous modifications and the following are possible within the scope of the invention. In particular, the number and the shape of the elastic and damping elements could be different, as well as the mode of connection of these elements with the structure, on the one hand, and with the inert mass, on the other hand. It would also be possible not to suspend the inert mass pendulumly to the structure, the elastic and damping elements being able, if necessary, also to fulfill the role of supporting the inert mass.

Claims (8)

 I. Device for attenuating the oscillations of structures or structures, in particular of slender structures such as chimneys, pylons, masts and similar structures, comprising an inert mass connected to the structure by elastic and damping elements constituted by one or more several cabled springs, characterized in that the cabled spring (s) (5, 15, 25) and their mode of connection with the structure (1, 11, 21) and / or with the inert mass (2, 12, 22 ) are designed so that the elasticity and damping effect of the wired springs are adjustable.  2. Device according to claim 1, characterized in that the cabled springs (5, 15, 25) and their mode of connection with the structure and / or with the inert mass are designed so that the elasticity effect and the damping effect of the wired springs are continuously adjustable.  3. Device according to claim 1 or 2, characterized in that the adjustment of the elasticity effect and the damping effect of the wired springs (5, 15, 25) is effected by adjusting the length useful springs wired between their points of connection with the structure and with the inert mass.  4. Device according to any one of the preceding claims, characterized in that the cabled springs are each in the form of a section of steel cable (5) in U shape, connected in an adjustable manner to the inert mass ( 2), on the one hand, and to the work (1), on the other hand, by the two branches (8, 9) of the U so that the length of the curved useful part (10) of the spring between the two fixing points (6, 7) is adjustable.  5. Device according to any one of claims 1 to 3, characterized in that each cabled spring is constituted by a section of steel cable (15) in the form of a loop with two U's, the two branches of which are connected to the inert mass (12), on the one hand, and the work (11), on the other hand, respectively at two fixing points (16, 17) spaced adjustable so as to allow an adjustment of the length of the two parts useful (20) opposite, curved, sections of steel cable between the structure and the inert mass.  6. Device according to claim 5, characterized in that the fixing devices (16, 17) of the steel cable section (15) are fixed relative to the inert mass (12) and relative to the structure (11) and are adapted to allow adjustment by displacement of the cable section relative to these devices.  7. Device according to Claim 5, characterized in that at least one of the two devices for fixing the section of steel cable to the inert mass, on the one hand, and to the structure, on the other hand , is adjustable in position relative to the inert mass or the structure.  8. Device according to any one of claims 1 to 3, characterized in that it comprises a single section of steel cable (25) shaped as a coil spring passing through the holes of four rings (26, 27 ) two of which (26) are connected to the structure (21) and two (27) to the inert mass (22, at least one of each of these two rings being adjustable in position along its axis.