Technical Field
[0001] The present invention finds application in the field of seismic devices and in particular
relates with a seismic device for the insulation of buildings and constructions in
general.
State of the art
[0002] At present the seismic isolation techniques for protecting buildings from destructive
violence of an earthquake involve the use of different types of isolation devices.
[0003] Among these, the most common systems involve the use of slide systems with overlapped
metal plates, systems with metal plates and rubber plates placed one over the other
in an alternate way, rubber cylinders with bases fastened to the structure, rolling
ball or rollers systems, simple or double pendulum systems.
[0004] WO95/23267 discloses an insulating device formed by a pair of overlapping plates having opposite
faces so shaped to define channels for housing rollers for the reciprocal sliding
of the plates.
[0005] The top plate is also provided with additional channels in which two further rollers
are housed and rotated 90° with respect to the lower rollers and on which a third
plate rests to support the construction.
[0006] In this way, the rollers can absorb the oscillations in a horizontal plane produced
by an earthquake.
[0007] The whole group of plates also rests on a group of elastic elements, in particular
high-strength springs, which have the task of absorbing the vertical oscillations.
[0008] The use of these cushioning systems for absorption of the vertical oscillations has,
however, some drawbacks, a first of which is represented by the high cost of such
systems. Furthermore, in the moment in which the absorption capacity of the loads
has to be varied, it is necessary to provide different type of springs or to vary
the number thereof, with possible problems of equilibrium of the device.
[0009] Moreover, in this case it is also necessary to proceed to the removal of the upper
plates, which is clearly not always feasible.
Scope of the invention
[0010] The object of the present invention is to overcome the above mentioned drawbacks,
by providing a seismic device for isolating buildings with high efficiency and relative
cheapness.
[0011] A particular object is to provide a seismic device for isolating buildings wherein
the properties of absorbing vertical loads and vertical oscillations produced by the
earthquake may be easily adjusted and adapted to the specific structure which the
device is applied to. Still another particular object is to provide a seismic device
for isolating buildings wherein the adjustment of the capacity of absorbing vertical
loads may also be obtained with the device in assembled condition.
[0012] These objects, as well others which will appear more clearly hereinafter, are achieved
by a seismic device for insulating buildings that, according to claim 1, comprises
a group of at least three plates mutually superimposed and having respective faces
facing each other and shaped to define, between each pair of facing plates, at least
one pair of channels, each of said channels housing at least one roller adapted to
allow relative sliding in a horizontal plane of said plates for absorption of horizontal
oscillations produced by an earthquake, the channels defined by the lower plate and
the intermediate plate having the extension direction perpendicular to the channels
defined between said intermediate plate and the top plate.
[0013] The device also comprises elastic damping means placed below said group of plates
to isolate it from the vertical oscillations caused by an earthquake and that comprise
a plurality of cushions inflatable at a predetermined controlled pressure and placed
below said lower plate to raise said group from the ground and absorb the load thereof
and the vertical oscillations produced by the earthquake.
[0014] In this way it will be possible to adjust the pressure of the cushions to the specific
load conditions in an easy and immediate way, simply by varying the inflation pressure
and without inserting or removing one or more damping elements.
[0015] Suitably, said cushions may comprise an elastomeric material inflating chamber provided
with an inflation/deflation valve, so as to adjust pressure in a simple manner.
[0016] Advantageously, the damping means may comprise a plurality of spacers adapted to
be disposed below said lower plate to maintain said group raised from the ground by
a distance sufficient to allow insertion of said cushions in the deflated condition
for their next inflation at the predetermined pressure.
[0017] In this way it will not be necessary to position the cushions already inflated but
the same may be introduced below the group of plates after placing the same group
and in deflated conditions so as to be gradually brought to the correct pressure value.
[0018] Advantageous embodiments of the invention are obtained in accordance with the dependent
claims.
Brief description of the drawings
[0019] Further features and advantages of the invention will become more apparent from the
detailed description of some preferred but not exclusive embodiments of a seismic
device for isolating buildings, illustrated by way of non-limiting example with the
aid of the accompanying drawing in which:
FIG. 1 is a front view of the lower plate of the group of the invention and of two sides
views of the same plate;
FIG. 2 is a front view of the intermediate plate of the group of the invention and of two
sides views of the same plate;
FIG. 3 is a front view of the top plate of the group of the invention and of two sides views
of the same plate;
FIG. 4 is a perspective view of the device of the invention in a first preferred embodiment;
FIGs. 5 and 6 are two front views of the device of Fig. 4 rotated of 90° with each other;
FIGs. 7 and 8 are two front views of a device in a second preferred embodiment rotated of 90° with
each other;
FIG. 9 shows two possible embodiments of the rollers;
FIG. 10 shows an inflatable cushion in an inflated condition and in a deflated condition;
FIGs. 11 and 12 are two front views of the device in a third preferred embodiment rotated of 90°
with each other;
FIGs. 13 and 14 are two front views of the device in a fourth preferred embodiment rotated of 90°
with each other;
FIG. 15 shows a detail of the devices of Figs. 11 to 14;
FIG. 16 shows the lower spacers of the device according a top view and side views.
Best modes of carrying out the invention
[0020] With reference to the attached figures, there are illustrated some preferred but
not exclusive embodiments of a seismic device for isolating building structures, such
as buildings, bridges and infrastructure in general, designed to be arranged in correspondence
of the supporting structures of a building in order to absorb the horizontal and vertical
oscillations produced by a possible earthquake.
[0021] In its most basic configuration, the device, shown assembled in the operating configuration
of
Fig. 4, comprises a group of three plates
1, 2, 3 overlapping each other and having respective faces facing each other shaped to define,
between each pair of facing plates, at least one pair of channels
12.
[0022] Each channel
12 houses one or more rollers
5 adapted to allow the relative sliding of the plates
1, 2, 3 in a horizontal plane for the absorption of horizontal oscillations produced by the
earthquake.
[0023] In particular, the channels
12 between the lower plate
1 and the intermediate plate
2 have a direction of development perpendicular to the channels
12 between the intermediate plate
2 and the top plate
3 of the group.
[0024] Elastic damping means are arranged below the lower plate
1 for absorbing the upper load and isolating the group of plates
1, 2, 3, and consequently the upper construction, from the vertical oscillations caused by
the earthquake.
[0025] The elastic damping means comprise a plurality of cushions
9 adapted to be inflated to a controlled predetermined pressure to raise the group
from the ground and absorb the load and the vertical oscillations produced by the
earthquake.
[0026] The number and the capacity of the cushions
9 may vary depending on the load and the size of the whole device, without particular
theoretical limitations.
[0027] The cushions
9 will comprise an inflation chamber made of elastomeric material, for example rubber,
provided with an inflation/deflation valve.
[0028] As shown from
Fig. 10, the inflation chambers may have an annular shape. In this figure, the chamber
8 is in the deflated configuration while the chamber
9 is in inflated condition.
[0029] The damping means also comprise a plurality of spacers
11 adapted to be arranged below the lower plate
1 to keep the group raised from the ground for a distance sufficient to allow insertion
of the cushions
8 in deflated condition for subsequently inflating them to the predetermined pressure.
[0030] In this way, through the introduction of hydraulic jacks or similar means it will
be also possible to temporarily bypass the device, for example in a maintenance phase.
[0031] The spacers
11 may be arranged directly on the ground or on a support
10 adapted to support the whole group of plates, as shown in
Fig. 16.
[0032] The spacers
11 are arranged along the perimeter of the lower plate
1, in a variable number according to the dimensional requirements, with heights that
can be selected in function of the dimensional features of the cushions
9, i.e. the height of the latter in the inflated condition, so that with inflated cushions
9 the lower plate
1 is raised with respect of the spacers
11.
[0033] From
Fig. 1, wherein the lower plate
1 of the group is shown, it is visible that the plate
1 has a flat lower face and a shaped upper face on which two concavities identical
with each other in shape and mutually parallel are realized, in relief or recessed.
[0034] Each concavity will define a rolling track for one or more rollers
5 and will face a corresponding concavity made in the lower face of the intermediate
plate
2, so as to define two channels
12 for housing respective rollers
5.
[0035] The channels
12 defined between the lower plate
1 and the intermediate plate
2 will be parallel to each other to confer to the rollers
5 a same direction of rolling, allowing the horizontal relative sliding between the
lower plate
1 and the intermediate plate
2 in a direction orthogonal to the axis of rotation of the rollers
5 for absorbing the respective horizontal components of the oscillations produced by
the earthquake.
[0036] The upper face of the intermediate plate
2 is also shaped with a pair of concavities or rolling tracks facing upwards and which
develop in a direction orthogonal to the concavities or tracks of the lower face.
[0037] Such concavities will face respective specular concavities of the lower face of the
top plate
3, so as to define two further channels
12 for housing and rolling the rollers
5, always parallel to each other to have a same direction of rolling.
[0038] These further channels
12 will develop orthogonally to the channels
12 defined between the lower plate
1 and the intermediate one
2 to allow the relative horizontal sliding between the top plate
3 and the intermediate plate
2 in a direction orthogonal to the axis of rotation of the respective rollers
5 and allow the absorption of the respective horizontal components of oscillations
produced by the earthquake.
[0039] In this way, the combined action of the rollers
5 arranged between the lower plate
1 and the intermediate plate
2 and of the rollers
5 between the intermediate plate
2 and the top one
3 will make it possible to absorb all the horizontal components of the stresses produced
by the earthquake.
[0040] The lower plate
1 and the top plate
3 will be substantially similar to each other and be mutually rotated by 180° on the
vertical plane and of 90° on the horizontal plane.
[0041] The rollers
5, of free-rolling type, self-centering, permanent and instantaneous for gravity will
be substantially cylindrical with a circular or elliptical base, with axial extension
close to that of the respective channels
12 and minimum diameter so to maintain the plates
1, 2, 3 mutually spaced apart in the vertical direction to prevent their mutual contact and
the consequent friction.
[0042] The rollers
5 will present a hard and smooth outer surface with low friction coefficient, possibly
mirror-polished, and may either be manufactured without guides or with removable guides,
as shown in
Fig. 9 wherein the rollers with guides are indicated by
6.
[0043] In turn, the concavities will be machined so as to have a hard and smooth outer surface
with low friction coefficient, possibly mirror-polished.
[0044] In this way the device will be highly effective in the absorption of oscillations
since the friction will be substantially null.
[0045] By contrast, the faces of the lower plate
1 and of the top plate
3 not provided with the concavities may be rough, with the top plate
3 having the upper face facing upwards that will constitute a single block with the
above structure, while its lower face will isolate the structure from the ground.
[0046] More than one roller
5 having axes of rotation parallel with each other may also be housed in each channel
12.
[0047] For example,
Figs. 7 and
8 show a device having two rollers
5 for each channel
12. In
Figs. 11 and
12 three rollers
5 are instead present in each channel
12, while in
Figs. 13 and
14 every channel
12 houses four rollers
5.
[0048] In the case of three or more rollers
5 for each channel
12, the side rollers will have diameter smaller than the one of the central rollers to
allow their insertion inside the channels
12 with a circular arc section.
[0049] Moreover, in case of more rollers
5 in the same channel
12, these rollers
5 will have the respective axes of rotation mutually coupled by connecting rods, struts
with bushings, ball bearings or other equivalent chain-mounted mechanisms, as shown
in
Fig. 15 wherein such means are indicated by
7, to maintain fixed the transverse distance of the rollers
5 and at the same time allow the rolling thereof, but preventing the rollers
5 to roll by gravity towards the center of the tracks, both in static conditions and
during an earthquake.
[0050] The dimensions of the various parts of the device are not limiting nor significant
for the present invention, as will be selected in function of the construction which
the device is designed for.
[0051] From above it appears evident that the device according to the invention achieves
the intended objects.
[0052] The device according to the invention is susceptible of numerous modifications and
variations, all falling within the scope of the present invention as defined by the
accompanying claims. All the details may be also replaced with other technically equivalent
elements, and the materials may be different according to requirements, without departing
from the scope of protection of the present invention defined by the appended claims.
1. A seismic device for isolating buildings, comprising:
- a group of at least three plates (1, 2, 3) overlapping each other and having respective faces facing each other shaped to define,
between each pair (1, 2; 2, 3) of facing plates, at least one pair of channels (12), each of said channels (12) housing at least one roller (5, 6) adapted to allow relative sliding in a horizontal plane of said plates (1, 2, 3) for the absorption of horizontal oscillations produced by an earthquake, the channels
(12) between the lower plate (1) and the intermediate plate (2) having a development direction orthogonal with respect to the channels (12) defined between said intermediate plate (2) and top plate (3) of said group;
- elastic damping means arranged below said group of plates (1, 2, 3) to isolate it from the vertical oscillations caused by an earthquake;
characterized in that said elastic damping means comprise a plurality of cushions
(9) inflated to a predetermined controlled pressure and arranged below said lower plate
(1) to raise said group from the ground and absorb the load and the vertical oscillations
produced by the earthquake.
2. Seismic device as claimed in claim 1, characterized in that said cushions (9) comprise an inflation chamber made of elastomeric material and provided with an inflation/deflation
valve.
3. Seismic device as claimed in claim 1 or 2, characterized in that said damping means comprise a plurality of spacers (11) adapted to be disposed below said lower plate (1) for maintaining said group raised from the ground by a distance sufficient to allow
the insertion of the deflated cushions (8) for their subsequent inflation to the predetermined pressure.
4. Seismic device as claimed in any preceding claim, characterized in that each shaped face of said plates (1, 2, 3) has a pair of identical and mutually parallel concavities, said concavities being
specular to the concavities of the shaped face facing it and having a circular arc-shaped
section.
5. Seismic device as claimed in claim 4, characterized in that said lower plate (1) and said top plate (3) have respective shaped faces identical to each other and are
arranged in positions rotated 90° with each other.
6. Seismic device as claimed in claim 5, characterized in that said intermediate plate (2) has two mutually opposite shaped faces each having a pair of concavities defining
the rolling tracks for said rollers (5, 6).
7. Seismic device as claimed in claim 6, characterized in that said concavities extend along mutually orthogonal directions parallel to the directions
of development of the concavities formed in the shaped faces facing thereto to define
respective housing channels (12) for said rollers (5, 6).
8. Seismic device as claimed in any preceding claim, characterized in that said rollers (5, 6) are sized with such a diameter as to hold said plates (1, 2, 3) mutually spaced apart and prevent the mutual contact.
9. Seismic device as claimed in any preceding claim, characterized in that each of said channels (12) houses at least two rollers (5, 6) having axes of rotation parallel with each other.
10. Seismic device as claimed in claim 9, characterized in that the rollers (5, 6) inserted in a same channel have respective axes of rotation mutually coupled by connecting
rod or bearing means (7) so as to maintain fixed the transverse distance and to allow the rolling.
11. Seismic device as claimed in claim 9 or 10, characterized in that said rollers (5, 6) have a decreasing diameter from the center of said channels (12) towards the side edges thereof.
1. Seismische Vorrichtung zum Isolieren von Gebäuden, umfassend:
- eine Gruppe von mindestens drei Platten (1, 2, 3), die einander überlappen und die jeweiligen einander zugewandten Flächen so geformt
sind, dass sie zwischen jedem Paar (1, 2; 2, 3) einander gegenüberliegender Platten mindestens ein Paar bilden Kanäle (12), wobei jeder der Kanäle (12) mindestens eine Rolle (5, 6) aufnimmt, die dafür ausgelegt ist, ein relatives Gleiten in einer horizontalen Ebene
der Platten (1, 2, 3) zur Absorption von horizontalen Schwingungen zu ermöglichen, die von einem erzeugt
werden Erdbeben, wobei die Kanäle (12) zwischen der unteren Platte (1) und der Zwischenplatte (2) eine Entwicklungsrichtung haben, die orthogonal zu den Kanälen (12) ist, die zwischen der Zwischenplatte (2) und der oberen Platte (3) der genannten
Platte definiert sind Gruppe;
- elastische Dämpfungsmittel, die unter der Gruppe von Platten (1, 2, 3) angeordnet
sind, um sie vor den durch ein Erdbeben verursachten vertikalen Schwingungen zu isolieren;
dadurch gekennzeichnet, dass die elastischen Dämpfungsmittel eine Vielzahl von Kissen (9) aufweisen, die auf einen
vorbestimmten gesteuerten Druck aufgeblasen sind und unter der unteren Platte (1)
angeordnet sind, um die Gruppe vom Boden anzuheben und die Last und die durch das
Erdbeben erzeugten vertikalen Schwingungen zu absorbieren.
2. Seismische Vorrichtung nach Anspruch 1, dadurch gekennzeichnet, dass die Kissen (9) eine Aufblaskammer aus einem elastomeren Material aufweisen und mit
einem Aufblas- / Ablassventil versehen sind.
3. Seismische Vorrichtung nach Anspruch 1 oder 2, dadurch gekennzeichnet, dass die Dämpfungsmittel eine Vielzahl von Abstandshaltern (11) umfassen, die so angeordnet
sind, dass sie unter der unteren Platte (1) angeordnet sind, um die Gruppe um einen
ausreichenden Abstand vom Boden zu halten ermöglichen das Einsetzen der entleerten
Kissen (8) für ihr nachfolgendes Aufblasen auf den vorbestimmten Druck.
4. Seismische Vorrichtung nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, dass jede geformte Fläche der Platten (1, 2, 3) ein Paar identischer und zueinander paralleler
Konkavitäten aufweist, wobei die Konkavitäten zu den Konkavitäten der ihr zugewandten
geformten Fläche spiegelnd sind und einen kreisbogenförmigen Abschnitt aufweist.
5. Seismische Vorrichtung nach Anspruch 4, dadurch gekennzeichnet, dass die untere Platte (1) und die obere Platte (3) jeweils identische Formflächen haben
und in zueinander um 90 ° gedrehten Positionen angeordnet sind.
6. Seismische Vorrichtung nach Anspruch 5, dadurch gekennzeichnet, dass die Zwischenplatte (2) zwei einander gegenüberliegende geformte Flächen aufweist,
von denen jede ein Paar Konkavitäten aufweist, die die Rollbahnen für die Rollen (5,
6) definieren.
7. Seismische Vorrichtung nach Anspruch 6, dadurch gekennzeichnet, dass sich die Konkavitäten entlang zueinander orthogonaler Richtungen parallel zu den
Entwicklungsrichtungen der Konkavitäten erstrecken, die in den dazu zugewandten Formflächen
ausgebildet sind, um jeweilige Gehäusekanäle (12) für die Rollen (5, 5) zu bilden.
6).
8. Seismische Vorrichtung nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, dass die Rollen (5, 6) einen solchen Durchmesser haben, dass die Platten (1, 2, 3) voneinander
beabstandet gehalten werden und der gegenseitige Kontakt verhindert wird.
9. Seismische Vorrichtung nach einem der vorhergehenden Ansprüche, dadurch gekennzeichnet, dass jeder der Kanäle (12) mindestens zwei Rollen (5, 6) mit zueinander parallelen Drehachsen
enthält.
10. Seismische Vorrichtung nach Anspruch 9, dadurch gekennzeichnet, dass die Rollen (5, 6), die in einem gleichen Kanal eingesetzt sind, jeweilige Drehachsen
aufweisen, die durch Verbindungsstangen oder Lagermittel (7) miteinander gekoppelt
sind, um den Querabstand fest zu halten das Rollen zulassen.
11. Seismische Vorrichtung nach Anspruch 9 oder 10, dadurch gekennzeichnet, dass die Rollen (5, 6) von der Mitte der Kanäle (12) zu deren Seitenkanten hin einen abnehmenden
Durchmesser aufweisen.
1. Un dispositif sismique pour isoler les bâtiments, comprenant:
- un groupe d'au moins trois plaques (1, 2, 3) qui se chevauchent et dont les faces
respectives se font face de manière à définir, entre chaque paire (1, 2; 2, 3) de
plaques opposées, au moins une paire de des canaux (12), chacun desdits canaux (12)
logeant au moins un rouleau (5, 6) adapté pour permettre un glissement relatif dans
un plan horizontal desdites plaques (1, 2, 3) pour l'absorption des oscillations horizontales
produites par tremblement de terre, les canaux (12) entre la plaque inférieure (1)
et la plaque intermédiaire (2) ayant une direction de développement orthogonale par
rapport aux canaux (12) définis entre ladite plaque intermédiaire (2) et la plaque
supérieure (3) de ladite groupe;
- des moyens d'amortissement élastiques agencés sous ledit groupe de plaques (1, 2,
3) pour l'isoler des oscillations verticales provoquées par un séisme;
caractérisé en ce que lesdits moyens d'amortissement élastiques comprennent une pluralité de coussins (9)
gonflés à une pression contrôlée prédéterminée et agencés sous ladite plaque inférieure
(1) pour relever ledit groupe du sol et absorber la charge et les oscillations verticales
produites par le séisme.
2. Dispositif sismique selon la revendication 1, caractérisé en ce que lesdits coussins (9) comprennent une chambre de gonflage en matériau élastomère et
munie d'une valve de gonflage / dégonflage.
3. Dispositif sismique selon la revendication 1 ou 2, caractérisé en ce que lesdits moyens d'amortissement comprennent une pluralité d'entretoises (11) aptes
à être disposées en dessous dudit plateau inférieur (1) pour maintenir ledit groupe
surélevé du sol d'une distance suffisante pour permettre l'insertion des coussins
dégonflés (8) pour leur gonflage ultérieur à la pression prédéterminée.
4. Dispositif sismique selon l'une quelconque des revendications précédentes, caractérisé en ce que chaque face profilée desdites plaques (1, 2, 3) présente une paire de concavités
identiques et parallèles entre elles, lesdites concavités étant spéculaires aux concavités
de la face profilée qui lui fait face. et ayant une section en forme d'arc de cercle.
5. Dispositif sismique selon la revendication 4, caractérisé en ce que ladite plaque inférieure (1) et ladite plaque supérieure (3) ont des faces conformées
respectives identiques l'une à l'autre et sont disposées dans des positions tournées
à 90 ° l'une par rapport à l'autre.
6. Dispositif sismique selon la revendication 5, caractérisé en ce que ladite plaque intermédiaire (2) présente deux faces de forme opposées ayant chacune
une paire de concavités définissant les pistes de roulement desdits rouleaux (5, 6).
7. Dispositif sismique selon la revendication 6, caractérisé en ce que lesdites concavités s'étendent suivant des directions orthogonales mutuellement parallèles
aux directions de développement des concavités formées dans les faces profilées qui
leur font face pour définir des canaux de logement respectifs (12) pour lesdits rouleaux
(5, 6)
8. Dispositif sismique selon l'une quelconque des revendications précédentes, caractérisé en ce que lesdits rouleaux (5, 6) sont dimensionnés avec un diamètre tel qu'ils maintiennent
lesdites plaques (1, 2, 3) espacées les unes des autres et empêchent le contact mutuel.
9. Dispositif sismique selon l'une quelconque des revendications précédentes, caractérisé en ce que chacun desdits canaux (12) loge au moins deux rouleaux (5, 6) ayant des axes de rotation
parallèles l'un à l'autre.
10. Dispositif sismique selon la revendication 9, caractérisé en ce que les galets (5, 6) insérés dans un même canal ont des axes de rotation respectifs
couplés mutuellement par des biellettes ou des moyens de support (7) de manière à
maintenir fixe la distance transversale et pour permettre le roulement.
11. Dispositif sismique selon la revendication 9 ou 10, caractérisé en ce que lesdits rouleaux (5, 6) ont un diamètre décroissant à partir du centre desdits canaux
(12) vers leurs bords latéraux.