DE69100215T2 - Load dissipation and limiting element. - Google Patents

Abstract

The present invention relates to a load dissipating and limiting element, for antiseismic devices and apparatus for bridges, viaducts, buildings and the like, comprising an elongated body (1) having restraining elements (2) at the ends thereof and, at an intermediate portion thereof, zones (3) tapering from the ends to the center portion thereof, and adapted to absorb elastic-plastic deformations. <IMAGE>

Description

The present invention relates to a load dissipation and limiting element specifically designed for anti-seismic devices and installations for bridges, viaducts, buildings and the like.

In previous patent applications of the same applicant (Italian patent applications No. 19538 A/86, and No. 19539 A/86, filed on February 26, 1986) anti-seismic devices are shown comprising specifically designed tilting pins, shown in Figures 1 and 2, which are provided essentially at one end thereof with a cylindrical part to which is coupled a part of variable cross-section tapering towards the opposite end where a spherically shaped part forms the end.

The pivot pins, held on the cylindrical part, are deformed so that they are bent according to a given curvature, under the effect of seismic forces applied to the spherical part.

These embodiments provide multiple advantages, for example, comparatively reduced cost, simple construction, reduced size, as well as multidirectional properties.

On the other hand, the mentioned pivots only allow rather limited sliding movements to take place; this disadvantage can be at least partially overcome by using the arrangements shown in Figures 3, 4 and 5, by diagrams which are statically and dynamically equivalent.

As should be obvious, these structures are very complex and expensive while in operation.

Patent documents IT-A-19538/86 or 19539/86 disclose a load dissipation and limiting element for anti-seismic devices having the features of the characterising part of claim 1.

SUMMARY OF THE INVENTION

Consequently, the aim of the present invention is to solve the problem described above by creating a dissipation element which, due to its specially developed construction, offers the possibility of overcoming all the difficulties associated with the above-mentioned limited sliding movements.

In fact, as is known, a seismic event causes abrupt displacements of the ground and consequently abrupt accelerations which, when transmitted through foundations, generate inertia forces, due to the large masses involved that make up a bridge, viaduct, building and similar structures.

It is also known that by using suitable decoupling devices, if they are suitably arranged, it is possible to reduce the inertia forces.

For example, in the case of bridges and viaducts, an elastic support was chosen that defines an oscillating system that, in practice, has a suspension for the construction mass that provides an appropriate has a resonance frequency that can be shifted from the characteristic frequencies of seismic events, so that the forces involved are greatly reduced.

However, in the characteristic curve of the above-mentioned restraints, after a first section of proportionality between the loads and deformations, there follows a section of abrupt increase, during which it is not possible to "control" the maximum force involved.

To solve this problem, other anti-seismic supports have been designed in which the above-mentioned section of proportionality is followed by a curve section in which the force is independent of the deformation, i.e. these supports have essentially a "plastic" effect.

In particular, these elastic-plastic action devices allow the possibility of reducing as well as controlling the maximum inertial forces transmitted by the supported masses (such as the mass of a viaduct) to the supporting structures (for example the column and shoulder structures), with self-evident advantages in the event of a high intensity seismic event.

From the dynamic point of view, the use of horizontal supports with essentially elastic-plastic characteristics corresponds to the introduction, close to a series of a type of suspension, of a load dissipation element, created with a very high load capacity and the due to its plastic deformations it creates a very advantageous ductile effect.

Consequently, through the above-mentioned dissipation, it is possible, under a high intensity seismic event, to obtain a large reduction in the response spectrum, in terms of the accelerations of the entire structural system, with a consequent large reduction in the loads on the supporting structures.

In this context, it should be emphasized that the anti-seismic devices were mainly used on road and railway bridges, because the current technology produces the latter as a continuous suspension bridge structure.

To the above it must be added that it is not possible to determine the main direction of seismic movements, therefore it will be necessary to develop multidirectional anti-seismic devices.

Within the scope of the above-mentioned aim, a main object of the present invention is to provide a load dissipation and limiting element which can be directly connected to the support structures and which allows to easily manufacture anti-seismic devices, separate from the support structures and adapted to create an efficient support system, exclusively on a horizontal plane.

Another object of the present invention is to provide such a load dissipation and limiting element which is of very simple construction and can be made easy and can be installed at comparatively reduced costs.

According to the present invention, the above-mentioned aims and objects, as well as other objects so far, which will become more apparent hereinafter, are achieved by a load dissipation and limiting element for anti-seismic devices and installations for bridges, viaducts, buildings and the like, having the features of the main claim 1.

Further advantageous features are claimed in the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS

Further characteristic features and advantages of the present invention will become more apparent hereinafter from the following detailed description of a preferred though non-exclusive embodiment of a load dissipation and limiting element according to the invention, illustrated by an indicative but non-limiting example in the accompanying drawings, in which:

Figures 1 and 2 show pivot pins, according to the state of the art, from a perspective view and as an elevation, respectively;

Figures 3, 4 and 5 show state-of-the-art applications that provide satisfactory mutual sliding movements;

Figure 6 is a perspective view illustrating the load dissipation or absorption and confinement element according to the invention;

Figure 7 shows an elevational view of the load dissipation and limiting element according to the present invention;

Figure 8 shows the load dissipation and limiting element of the invention in an assembled state, which is conceptually analogous to those shown in the prior art;

Figure 9 is a schematic view illustrating a possible embodiment of an anti-seismic device using the load dissipation and confinement element according to the present invention;

and

Figure 10 is a cross-sectional view taken along line X-X in Figure 9.

DESCRIPTION OF THE PREFERRED EMBODIMENT

With reference to the figures of the accompanying drawings, the load dissipation and limiting element, specially designed for anti-seismic devices and installations for bridges, viaducts, buildings and the like, according to the invention, comprises an elongated body, designated as a whole by the reference number 1, which is advantageously made of a steel material having high elongation characteristics (elongation to failure).

At the ends thereof, the body 1 is provided with holding parts, which preferably, although not necessarily, comprise cylindrical parts 2.

At the main part thereof, each load dissipation and limiting element, more simply called "pin", is created with a double tapered part 3 converging from the ends towards the main part thereof.

Each tenon is designed to create the desired displacements and reactions and its size is designed so that the major portions of the material forming the shaft thereof are subjected to plastic deformations i.e. the tapered portion thereof so as to create the desired ductile action.

The "pins" are retained by the plates 10 of the anti-seismic devices or support structures by means of the end holding parts 2, subjected to a relative displacement during the seismic event.

One of the two retaining parts can be removed to allow the above-mentioned relative displacement of the plates without causing the tenon shaft to be extended.

The shape of the cross section of the shaft can be circular, in which case an isotropic effect will be obtained with respect to the displacements and reactions, or of any desired shape (for example, of elliptical shape), in which case an anisotropic type of effect will be obtained while maintaining the important characteristics of a multidirectional property.

Figures 9 and 10 show an anti-seismic device, made using the pins disclosed above, and comprising two end plates 10 which retain these pins.

More specifically, the base plate is anchored to the substructure by means of the holding parts 11, whereby the top plate is coupled to the superstructure by a cup-shaped dome part 12, in turn anchored by holding parts 13.

The mutual movement under and over the structure deforms the tenons 1 and the provision of the cup-shaped dome part 12 allows to absorb the displacement relative to the end plates, the displacement caused by second order effects resulting from the deformations of the tenons, without subjecting the latter to any tension loads.

As explained, the same effect can also be achieved by using removable sleeve-shaped retaining elements.

In the embodiments shown in Figures 9 and 10, a circular geometry is created; of course, any arrangement of the pins is possible, for example, a square geometry, rectangular geometry and the like.

The use of the pin disclosed above provides a solution equivalent to that according to the prior art, shown in Figures 3 to 5, with much simpler construction means.

In fact, in the diagram of the prior art, the upper and lower hinges rotate by the same amount under the influence of the displacement of the two end plates, due to symmetry; also, the load dissipation and limiting element according to the invention creates the same effect, because it is designed to amplify mutual displacements, with the same length, with respect to the pins and with the same rigidity of the system.

To the foregoing, it must be added that the device according to the present invention can also be realized with other devices, such as small keys with predetermined fracture surfaces to remove the elastic part from the characteristic curve, as well as with pressure pistons or other hydraulic devices to absorb slow movement (for example, resulting from thermal effects) without loading the pins.

The pins according to the present invention can be used for any supporting structure (for example made of neoprene, steel, polytetrafluoroethylene, etc.), in the same way as that shown in the above-mentioned patent applications IT-A-19538/86 and 19539/86.

The invention as disclosed is susceptible to several modifications and variations, all of which fall within the scope of the invention as defined in the appended claims.

In putting the invention into practice, the material used as well as the specific sizes and shapes may be any according to requirements within the scope of the claims.

Claims (7)

1. A load dissipation and limiting element for an anti-seismic support structure for bridges, viaducts, buildings and the like, said element comprising an elongated body (1) made of a material capable of absorbing elastic-plastic deformations, having retaining means (2) at the end parts thereof for connecting said body to said structure by inserting said retaining means in openings provided in opposite parts (10) of the support structure, characterized in that said body is provided at an intermediate part thereof with regions (3) tapering from said end parts towards the centre thereof, and in that said retaining means have a substantially cylindrical shape. 2. A load dissipation and limiting element according to claim 1, characterized in that said tapered regions (3) have a circularly shaped cross-section in order to create an isotropic effect with respect to the displacements. 3. A load dissipation and limiting element according to one or more of the preceding claims, characterized in that these tapered regions (3) have cross-sections different from the circular shape in order to create an anisotropic effect with respect to the displacements. 4. An anti-seismic installation comprising a load dissipation and limiting element according to one or more of the preceding claims, characterized in that at least one of the end parts of the body (1) is coupled to end plates (10) by a removable sleeve-shaped retaining device. 5. An anti-seismic installation comprising a load dissipation and limiting element according to one or more of the preceding claims, characterized in that said body (1) is mounted between movable parts of said support device to cause said installation to follow a predetermined characteristic anti-seismic load/deformation curve. 6. An anti-seismic installation comprising a load dissipation and confinement installation according to claim 4, characterized in that said installation comprises a plurality of bodies (4) connecting said plates (10) which are subjected to mutual displacements during a seismic event in order to create a predetermined effect in terms of displacements and reactions. 7. An anti-seismic support structure including at least one load dissipation and limiting element according to any one of the preceding claims, characterized in that said structure further comprises a second order effect compensation member so as to allow the end plates, coupling a plurality of load dissipation and limiting elements, to move relative to each other without subjecting said load dissipation and limiting elements to any extensional or tensional loads.