FR2558879A1 - DEVICE FOR PROTECTING A COLUMN OR A PYLONE AGAINST EARTHQUAKES - Google Patents

Abstract

The invention relates to an omnidirectional vibration isolator with heavy internal damping, intended to protect the columns or pylons from the effects of an earthquake. Two thick steel plates 2 and 3 clasp, via cone-shaped elastomer pads 15 and 15', a sandwich structure composed of one thick steel plate 4 and one thin steel plate 4', which plates are connected together via an elastomer with heavy internal damping 13. Compression bars 10, fitted with "Belleville" washers 11 provide, at the same time, the mechanical connection between the plates 2 and 3 of the vibration isolator, and the precompression of the cone-shaped pads 15, 15', in such a way as to prevent separation of the elastomer. The isolator assembly is rigidly fixed onto a structure 1 connected to the ground. This vibration isolator may also be used in mechanical construction and civil engineering.

Description

 The present invention relates to a device for protecting a column and a pylon against the effects of dynamic stresses due to an earthquake. The vibration isolating element according to the invention can be used in a large number of applications where it is a question of subtracting a given material from stresses.

There are a wide variety of vibration isolators
However up to now, these insulators are characterized by extremely reduced vibration damping properties.

In addition, in existing devices, in particular that described in patent 2,316,412 (French patent), it is not easy to act separately on the damping characteristics and on the insulation characteristics, which represents a very serious drawback when it is a question of producing a vibration isolator responding to a determined excitation system.

The present invention proposes to provide a vibration damper which, while having a very high damping, further allows, by its design to separately adjust the insulation characteristics according to the particular cases encountered in practice. Another peculiarity of this vibration isolator is that it is omnidirectional, that is to say that in the event of an earthquake, the vertical and transverse displacements can be made simultaneously, hence the interest of having the same frequency clean in all directions. Recall that the maximum acceleration in an earthquake spectrum is between 3 and 10 Hz, hence the maximum amplitudes in this frequency band. However, the natural frequencies of the columns are themselves generally very low (of the order of 3 to 5 Hz), so that in the case of a material rigidly fixed to the ground, the modes of bending of the columns are constantly excited, thus bringing severe stresses of bending and risks of if we look at an earthquake spectrum, like that of EL
CENTRO, for example, we realize that it is not possible to completely isolate the material from ground movements, because we would have to adopt a natural frequency of suspension so low that the static stability of the whole does not In principle, we admit that we should not go below 1.2Hz, the amplitudes of movement below this frequency being too large. The principle of an anti-seismic suspension therefore consists in placing the resonance frequency between the low limit frequency of 1.2 Hz and a frequency lower than the bending frequency of the column to be protected. This replaces the response of the column, thereby reducing the stress on the equipment in the event of an earthquake or explosion.

 The present invention aims to provide a solution to the problem of earthquake resistance of columns, pylons, etc. According to this invention, the device for protecting a column against the effects of dynamic stresses, in particular of seismic origin , consists of at least one anti-seismic damper element, composed of an elastomer plate clamped between a first and a second metal plate, characterized in that said elastomer plate has recesses on at least one of its faces located opposite one of said metal plates, so as to come into contact with the neighboring plate only on a reduced surface, the depth of the recesses being sufficient to allow the parts remaining in relief and in contact with the neighboring plate being deformed under the effect of a force tending to move one of the metal plates in its plane with respect to the other, and under the effect of a force tending to bring together or move apart the one of the plates metallic with respect to each other, so as to absorb at least part of the energy brought into play by said efforts.

The invention will be better understood from FIGS. 1 to 80 FIG. 1
represents an existing shock absorber. Figure 2 represents an anti-seismic shock absorber element according to the invention. Figures 3 and 4 show variants in the form of the elastomer. 1 shows a known shock absorber composed of 6 elements each comprising an elastomer plate composed of neoprene, between two metal plates. This elastomer plate during a seismic shock comprising both a horizontal and vertical movement is subjected shear and compression, however this kind of vibration isolator was designed only to resist shear.

Figure 2, 2a, 2b shows a vibration damping element according to the invention. It comprises an elastomer plate 13 between two metal plates 4 and 4 ′. This elastomer plate has fairly deep grooves and preferably arranged , in a visible section in Figure 2a. During a horizontal movement due to a vibration in the direction of the arrow (Figure 2b), the grooves of the elastomer plate are deformed, so that at the simple shearing is superposed bending effects. If a priori we do not know the direction of the force due to the vibration, it is advantageous to provide on the two faces of the elastomer plate 13 with two series of grooves 131 and 132 in two different directions, preferably perpendicular without for this to be mandatory.

as shown in Figure 2a.

During vertical forces, the elements projecting relative to the mass of the elastomer, also deform by compression and by bending. So that the metal plates, one of which is secured to the excitation source and the area of the material to be suspended, are secured to the elastomer, the latter is bonded or adhered (adhesion of
the elastomer on the metal support, by vulcanization and under pressure)
A complete shock absorber may include a multitude of elements such as those described. The upper plate 4 of an element devr lower plate 4 ′ of the element placed above. By symmetry, a complete element may preferably be of circular or polygonal external shape, the latter form making it easier to attach to an existing structure. For convenience in certain cases, the element may in its center include a hollowed out part. Another alternative embodiment is shown in FIG. 3 in which, to avoid carrying out machining on both sides of the elastomer, two series are created of perpendicular grooves on one side so that there are prismatic elements, here parallelepipedic in contact on one of their faces with one of the plates 4 or 4 '. By extension the parallelepipedic elements can be simply modified and become cylindrical elements (fig. 4), so as to respond identically for any direction of stress.

The invention also includes a complete damper using at least one damper element according to one of the variants described above and shown in Figure 5 -5 a.

 A central element comprising the metal or composite material plates 4 and 4 ′ as well as the elastomer plate or plates 13, is provided with a recessed part so as to allow the passage and the fixing of a column to be protected, example the column 6 can be made integral with the plate 4 by means of a fixing flange 7 and the bolts 8, or by some other anchoring process whatsoever.

 The assembly of the sandwich composed of the plates 4,4 'and of the elastomer 13 is integral with anti-vibration elements of conical shape 15 and 15', made of elastomer, intended to allow the vertical and horizontal displacements of the column 6. Under the combined action of vertical and horizontal forces during an earthquake, the plates 4 and 41 deform slightly in flexion, and slide relative to each other, the viscoelastic material 13 is then subjected to a strong degradation of energy and gives good results if the sizing of the sandwich is optimized, there are calculation methods - and the process is not new.

 The innovation consists, among other things, of using an elastomer with high internal damping, with poor mechanical properties and an elastomer with good mechanical properties to take up the forces.

The elastomer with high internal damping takes various forms s
doubly ribbed geometrical (ribs in any two directions or orthogonal) - figure 2, parallelepipedic studs figure 3, cylindrical studs, figure 4
The invention will not be modified if the elastomer layer 13
is full, simply the vibration isolator is less efficient.

The invention will now be described in more detail, with reference to a particular embodiment given by way of example.
and shown in the accompanying drawings The vibration isolator assembly
rests on a metal structure 1, integral with the ground A steel plate
2, very thick, provided with a central hole for the passage of the
column 6, is rigidly fixed to the structure 1 by bolts or by welding points A steel plate 3, of very thick, ensures
both the role of precornpressibn plate and mechanical stop in case
loss of adhesion of elastomer 5 or defective bonding thereof
The plate 3 also has in its center, a recess to allow the passage of the column 6. The plates 2 and 3 are made of steel, coated with a protection against external aggressions (humidity, ozone, saline atmosphere, etc.). . The plate 4 is very thick in front of the plate 4 ', because it must take up the forces (weight, forces due to bending); the invention will not be modified if the very thick plate is located in the lower position, at the place of plate 4 '. The elastomer 5 must have good mechanical properties; the conical rings 15 and 15 ′ provide the connection between the lower plate 2, the upper plate 3 and the shock-absorbing sandwich assembly 4-4′-13, their conicity, very important, determines a unique natural frequency in all the horizontal and vertical directions. The bonding of the Savast elastomer with the 2-3-4-4 'plates is made by hot adhesion or by gluing. Precompression bars 10 in FIG. 6 are distributed uniformly around the periphery of the plates 2 and 3, on the one hand they provide a rigid connection between the plates 2 and 3, on the other hand serve as mechanical stops for the horizontal movements of the sandwich 4 -4'-13. A stack of Belleville washers 1 1 resting on a sheath 9, makes it possible to modify the spacing of the plates 2 and 3, as a function of the tightening torque provided to the nut 12.11 results, a compressive force on the elastomer 5; thus one modifies point of
operation of the vibration isolator on the stress-strain curve.

At high tightening torque, the operating point moves towards
at the top, at a low tightening torque, it moves down.
required rigidity of the vibration isolator, plates can be placed
metal 14-14 ', ring-shaped to increase the stiffness of
it together. This number of rings is variable depending on the stiffness requested.

In Figure 8 we have shown a variant of the complete insulator
vibration as it appears in figure 5.

Of course, innovation is not strictly limited to
examples which have been given above, this is how we will not depart
not the subject of the invention by embodiments which would not differ from it
only by details, or which would apply to the feet of pylons,
construction parts, rotating or supporting machine supports
reciprocating movement.

Similarly the relative positions of the sandwich 4-4'-13 (part
mobile) compared to plates 2-3 (fixed part), can be reversed.

To illustrate this patent, we give an example of a concrete case, to
know how to isolate a high voltage line porcelain insulator from an earthquake.

- height of column 7, su.

-mass of the column 1500Kg.

- vertical force of 10. OOON, due to a sudden break in the current.

- bending moment applied to the sandwich 46.300 N. m.

- dimensions of plates 2 and 3 610mm. x 610mm.

- column diameter 310mm.

- thickness of the upper plate 4 - 25mm.

- thickness of the lower plate 4 '- 5mm.

- thickness of the elastomer layer 6mm., loss angle # = 50 '
ss = 1.19 it is the ratio of the imaginary part of the shear modulus - to the real part.

- about 20% structural damping - average vertical stiffness of the sandwich 4-4'-13 Kz = 56.2x106 Nm-1.

- transversal stiffness of the sandwich 4-4'-13 Kx = 90, 5x108Nm? - stiffness in rotation K α = 4, 3x106Nm-1 / rad.

- rotation angle <= 0.61 - natural frequency of rotation 1.55 Hz.

Claims (10)

 1- Anti-seismic damper element, composed of at least one elastomer plate clamped between a first and a second metal plate, characterized in that said elastomer plate has recesses on at least one of its faces located opposite one of said metal plates, so as to come into contact with the neighboring plate only on a reduced surface, the depth of the recesses being sufficient to allow the parts remaining in relief and in contact with the plate close to being deformed under the effect of an effort tending to move one of the metal plates in its plane relative to the other, and under the effect of an effort tending to move one of the metal plates closer or further apart to the other, so as to absorb at least part of the energy brought into play by said efforts.  2- anti-seismic damper element according to claim 1, characterized in that the recesses constitute grooves facing at least one of the InétalllquesO plates  3- shock absorber element according to claim 2, characterized in that said grooves facing the first metal plate have a different orientation from those located opposite the second metal plate.  4-damper element according to claim 1, characterized in that the recesses leave in relief prismatic volumes facing their base with the first and / or a second metal plate.  5-anti-seismic damper element according to claim 1, characterized in that the recesses leave in relief cylindrical volumes opposite by their base with the first and / or the second metal plate.  6-anti-seismic damper element according to any one of claims 1 to 5, characterized in that the elastomer plates are bonded to the neighboring plates.  7-anti-seismic damper element according to any one of claims 1 to 5, characterized in that the elastomer plates are adhered to the neighboring plates. Adhering consists in vulcanizing hot and under pressure, the elastomer on the support, during manufacture.  8-anti-seismic damper element according to any one of claims 1 to 7, characterized in that the shape of the element is polygonal.  9- anti-seismic damper element according to any one of claims 1 to 7, characterized in that the shape of the element is circular  10-damper element according to any one of claims 1 to 9, characterized in that the element comprises in its center a part avoids  ll-Seismic shock absorber characterized in that it preferably comprises at least one element according to any one of claims 1 to 10, and in that the first metal plate of an element constitutes the second metal plate of the contiguous element. - 12-Anti-seismic damper according to claim 11, characterized in that the various elements of the damper are placed symmetrically on either side of a central element.  13 - Anti-seismic shock absorber according to claim 12, characterized in that the elements placed on either side of the central element are constituted so as to give the shock absorber a generally biconical shape in two superimposed truncated cones and symmetrical, the bottom plate e of each of the two truncated cones constituting one of the metal plates of each of the two extreme damper elements, and projecting therefrom so as to allow the passage of the clamping rods intended for on the one hand to exert precompression on all of the damper elements, on the other hand to limit the displacement of the central element during an earthquake.