Patent Description:
More in detail, the present invention relates to the fixing of sheet-like elements, in particular made of glass or the like, to a support structure, so as to define a structure for delimiting or containing people, animals and/or things.

Normally, said support structure may comprise a building component such as terraces, floors, balconies, or in general any walkable support surface arranged substantially horizontally.

The invention, therefore, falls within the building field, particularly in the sector of architecture.

Of course, nothing prevents the application of the invention to be extended also to fields different from the building one, such as for example nautical.

It is known that said delimiting or containment structures must meet and comply with specific safety standards, in particular relating to the loads they can be subjected to, so as to guarantee the protection and safety of persons or property. For example, said containment structures must be able to oppose and withstand an impact by a semi-rigid body (in accordance with UNI EN12600), i.e., they must withstand an impact with things, animals, people, provided and imparted in the most heavy position.

Said structures, therefore, must have the capacity to withstand, but without causing damage or injury, sudden and accidental impacts by things, animals or people. There are different mounting and fixing solutions, which secure the sheet-like elements to a building component.

For example, metal profiles are known, which can be anchored to the building component, adapted to act as a seat and support for said elements, retaining them fixed and stable even under the action of a load.

Said profiles are able to absorb and withstand the load, keeping the sheet-like element substantially unloaded.

Such solution allows meeting the safety standards, but at the same time increases the weight of the containment structure and alters its visual impact.

In particular, said profiles, due to their dimensions and their non-transparency that makes them very visible, change and "dirty" the line and the design of the containment structure, negatively affecting the aesthetic impression created.

In fact, said containment structures must be able to fully carry out their safety function and at the same time maintain satisfactory and pleasant aesthetic standards, so as to allow their use also in valuable architectural contexts.

To overcome such drawbacks, fixing means have been made, capable of locking and anchoring the plate-like elements directly to the building component; in general, said sheet-like element is installed to the shoulder of said building component.

Said fixing means, here called "boss constraint" or "constraint points", allow improving the visual impact by eliminating the use of metal profiles and provide a constraint means capable of guaranteeing the safety conditions.

The boss constraint, however, limits the resistance of the containment structure to an accidental impact, such as for example a soft-body impact.

In fact, said boss constraint, being rigid, does not support the deformation of the sheet-like element, creating the conditions for the breaking of the same.

We may consider, for example, a person who hits a generic balustrade.

The plate-like element reacts to the load by bending, in particular in the upper part subject to the load, while the point constraint reacts rigidly, preventing the lower part of the plate-like element from bending (the lower part of the plate-like element is that constrained to the building element).

The sheet-like element, therefore, cannot fully and freely support the deformation which it is subjected to; a criticality is thus generated capable of compromising the structural integrity through breakage and/or fracture.

To obviate such drawback, point constraints provided with elastic means, such as for example springs, have been made so as to allow partial yielding along the axis orthogonal to the plane defined by the plate-like element.

Therefore, said solution provides for a translation of the point constraint along its longitudinal axis, that is, orthogonal to the sheet-like element, in order to offer greater freedom of movement to the lower part of the same sheet-like element. However, the use of said elastic means has not definitively resolved the problem of the resistance to the impact by semi-rigid body of the containment structure.

In fact, said yielding of the point constraint cannot allow and support the various possible movements of the sheet-like element, which therefore, in the event of an impact, remains strongly stressed in the zone neighbouring the point constraint. Document <CIT> discloses a solution of the prior art, and more in particular a device for connecting two components, which comprises a clamping element, which is guided axially displaceably on a shank of a screw and has an outer conical surface, and a radially expandable clamping ring having an inner conical surface. The clamping element is inserted into the clamping ring in such a way that the outer conical surface of the clamping element abuts the inner conical surface of the clamping ring.

The main object of the present invention is to obviate the drawbacks set forth above by providing one or more bosses for the fixing of panels to a support structure, in particular for the making and installation of balustrades, parapets, barriers or similar architectural elements, capable of at least elastically supporting the movements of said panelling when stressed by one or more loads.

A further object of the present invention, at least for one or more executive variants, is to provide a boss system that facilitates the fixing of at least one panel to a support structure.

A further object of the present invention, at least for one or more executive variants, is to provide a boss system that reduces the size and dimensions of the boss.

A further object of the present invention, at least for one or more executive variants, is to provide a boss system that limits the number of components necessary for the installation and operation of the boss.

A further object of the present invention, at least for one or more executive variants, is to provide a boss system capable of providing a cushioning effect to dissipate the impact energy transmitted by a force.

This and other objects, which shall appear clear hereinafter, are achieved with an elastic fixing system of one or more panels to a support structure, illustrated in the following description and in the annexed claims that constitute an integral part of the same description.

Further features of the present invention shall be better highlighted by the following description of a preferred embodiment, in accordance with the patent claims and illustrated, purely by way of a non-limiting example, in the annexed drawing tables, in which:.

The features of the invention are now described using the references in the figures. It should be noted, also, that any dimensional and spatial term (such as "lower", "upper" , "inner", "outer", "front", "rear", "vertical", "horizontal" and the like) refers, unless otherwise indicated, to the position according to which the object of the invention is shown in the drawings, which does not necessarily coincide with the position of the same in operating conditions.

With the purpose of highlighting some features instead of others, not necessarily what described in the annexed drawings is perfectly to scale.

By rest position it is meant the position maintained by the elements of the invention when not subjected to sudden external stresses.

The term balustrade, without any limiting intent, hereinafter is to be understood as any type of infrastructure, of any material and shape, adapted to define a delimiting and/or containment structure for people and/or animals and/or things (balustrades, parapets, barriers or similar architectural elements).

Without any limiting intent, for description simplicity, hereinafter the term panel is to be understood as any substantially plate-shaped structural element adapted to define a balustrade or a parapet, such as for example panellings, polycarbonate sheets, glass sheets, wood, etc..

As clearly shown in the accompanying <FIG> indicates, as a whole, the fixing and connection system of one or more panels <NUM> to a support structure <NUM> (hereinafter structure <NUM>) according to the present invention.

In general, said structure <NUM> may consist of a building element such as terraces, floors, balconies or in general any walkable support surface arranged substantially horizontally, fully or partly made of masonry and/or metal carpentry and/or wood or other.

Said fixing system <NUM> comprises at least one elastic boss <NUM>, <NUM> adapted to an elastically yielding anchoring of the panel <NUM> to the structure <NUM>, for example to a shoulder <NUM> thereof lying substantially vertical.

Each of the two bosses <NUM>, <NUM> provides elastically yielding locking means adapted to allow a rotation and possibly also a translation of the panel <NUM> with respect to said shoulder <NUM>.

According to the invention, with reference to <FIG>, each of said bosses <NUM>, <NUM> is anchored to the shoulder <NUM> by means of a shank <NUM> and provides an elastically yielding body <NUM>, in turn comprising:.

said elastically yielding body, by means of said elements assembly <NUM>, <NUM>, <NUM>, being able to oppose yields due to a load F substantially orthogonal to the lying plane of the panel <NUM> with an elastic reaction force Fe substantially parallel to the lying plane of the panel <NUM>.

With reference to the sliding surface <NUM> it should be noted that by "irremovably constrained" it is to be understood that said sliding surface <NUM>, once installed and fixed on said shank <NUM>, is fixed and stable so as to act as a guide and stop means for the movement of the sliding element <NUM>.

However, it should be understood that said sliding surface <NUM> may be unmounted and removed from the shank <NUM>.

What has been said may be substantially extended also to the fixing of the shank <NUM> to the shoulder <NUM>.

In conclusion, said sliding element <NUM>, following an impact force F exerted thereon by the panel <NUM>, is pushed to slide along said sliding surface <NUM> and to press against said elastic opposing means <NUM> that oppose said force F with an elastic reaction force Fe that is substantially orthogonal to the same force F. What has been said applies to both bosses <NUM> and <NUM> that are capable of opposing also the torque C (shown in the figure by the torque of forces Fc) in the same way. Said elastic opposing means <NUM>, symbolized in the figure by spiral springs, may be of any type such as O-rings or other compression and pulling elastic elements. The elastic boss <NUM>, <NUM> is now described in accordance with a possible and preferred embodiment variant of the present invention.

According to such variant, the fixing system <NUM> to the structure <NUM> comprises:.

With the numerals <NUM>. a and <NUM>. b and with <NUM>. a and <NUM>. b, functionally different elements have been indicated, respectively, with different specific structural features adapted to carry out different tasks, in particular:.

Said functional elements may advantageously coincide by shapes and materials so as to maintain a reduced number of components, i.e.:.

a and <NUM>. b, each therefore provide specific structural features compatible with the functions they must carry out, but nothing prevents the use of a same container body <NUM> substantially comprising the structural features of both so as to limit the number of components necessary to the invention, or that it may differentiate for secondary constructional details, although still functionally equivalent; for example, the threads <NUM> may be replaced by alternative fixing means such as joint-wise couplings or the like.

Similarly, also <NUM>. a and <NUM>. b each provide specific structural features compatible with the functions they have to carry out, but nothing prevents the same component <NUM> to substantially comprise the structural features of both.

For the sake of clarity, therefore, the suffixes ". b" distinguish between two components that may carry out alternative and completely different functions while being usefully of identical shape.

Said elastic boss <NUM>, <NUM> is characterised in that the kinematic chain consisting of the elements container body <NUM>. a, sliding ring nut <NUM>. a, elastically yielding body <NUM>, shank <NUM>, carry out an elastic coupling capable of allowing elastic translation and/or rotation movements of the panel <NUM>, with respect to the shoulder <NUM>, when this, subject to an accidental and impulsive load represented by a force F, transmits a torque C and an applied force Fa parallel to the longitudinal axis x-x of the same boss <NUM>, <NUM>.

Said applied force Fa comprises a pulling Ft or pressing Fp force, where by pulling force Ft it is meant a force tending to move the panel <NUM> away from the structure <NUM> and by pressing Fp a force tending to bring the panel <NUM> close to the structure <NUM>.

Said elastic coupling, therefore, allows the panel <NUM> to yield elastically in response to at least some types of impacts it may receive reducing their destructive or traumatic effect against the persons who hit it and/or protecting the same panel <NUM> from possible breakages.

Said elastic coupling is capable of transforming and converting the longitudinal stress (axial along the shank <NUM>) generated by the said pulling Ft or pressing Fp force to a transverse stress (radial with respect to the shank <NUM>) Fr, said transverse (radial) stress Fr being absorbed and cushioned by the elastic deformation undergone by said elastic coupling.

Said elastic coupling, therefore, by attenuating and dissipating said applied force Fa, deforms accumulating elastic energy.

Said elastic energy, once the stress and the effect of the said applied force Fa is over, allows the elastic coupling to return to the rest position, bringing the panel <NUM> back to the original position.

Optional closing and finishing means are possible, which, besides preserving the aesthetics of the boss, also provide protection from dirt, dust, atmospheric agents or the like for the components making said boss <NUM>, <NUM>.

Such closing means may provide different solutions according to the position of the container body <NUM>, <NUM>. b whereon they are installed, for example they can comprise:.

Said plurality of finishing elements comprises a first tubular element <NUM> fixed, by screwing, along said threaded portion <NUM>, or interlocking, to said container body <NUM>, <NUM>. a, 30b, a second tubular element <NUM> insertable, at least partially, inside said first tubular element <NUM>, a helical spring <NUM> arranged between said second tubular element <NUM> and said container body <NUM>, <NUM>.

Said spring insists on the second tubular element <NUM> and on a shoulder <NUM> obtained on said container body <NUM>, <NUM>.

During the installation step, said plurality of finishing elements allows, thanks to the thrust provided by said helical spring <NUM>, bringing the second tubular element <NUM> in contact with the shoulder <NUM> of the building element <NUM>, guaranteeing the desired aesthetic finishing and protection of the components.

Moreover, in the event of impact and consequent rotation of the panel <NUM>, said helical spring <NUM> allows said second tubular element <NUM> to slide more inside said first tubular element <NUM>, so as to support the deformation movement of the boss in response to the thrust of the said panel <NUM> (<FIG>).

Alternatively, said plurality of finishing elements may be replaced by a sleeve, couplable by screwing or jointing to said container body <NUM>, <NUM>. b, made of yielding material.

Advantageously, as previously stated and as illustrated in the figures, said container bodies <NUM>. a and <NUM>. b may respectively provide a single container body <NUM>, with the same shapes and materials, so that said container body <NUM> may fulfil and meet two different needs.

With reference to the accompanying figures, a possible embodiment variant of the boss according to the present invention will now be described by way of a non-limiting example.

The boss will be distinguished here with the numerals <NUM> and <NUM> to indicate when used as an upper <NUM> and lower <NUM> boss, said bosses being substantially different in the arrangement of the means and the elements composing them.

The boss <NUM> is capable of responding elastically to a pulling force Ft in addition to a torque C, while the boss <NUM> is capable of responding elastically to a pressing force Fp in addition to a torque C.

<FIG> show a central bush <NUM> provided with a through hole <NUM>, for the passage of the shank <NUM>, and with suitable coupling/jointing means <NUM>, substantially a plurality of suitably shaped projections.

Said central bush <NUM> may advantageously be provided with at least two holes <NUM> that allow, as will be illustrated below, adjusting its position along said shank <NUM> from the outside.

<FIG> illustrate an eccentric bush <NUM> provided with a through hole <NUM> adapted to receive and couple with said central bush <NUM>.

Said through hole <NUM> is not concentric with respect to the longitudinal axis of said eccentric bush <NUM>; this facilitates the mounting and adjustment operation of the various elements during the panel installation step <NUM>.

Said eccentric bush <NUM> may advantageously be provided with at least two holes <NUM> that allow, as will be illustrated below, adjusting its position along said shank <NUM> from the outside.

Nothing prevents, in accordance with a possible executive variant, to make said central bush <NUM> and eccentric bush <NUM> in a single element <NUM>-<NUM>.

<FIG> show a possible executive variant of a container body <NUM>, usable both as a sliding container body <NUM>. a and as a stop container body <NUM>. b, i.e., as mentioned, the variant described herein of said container body <NUM> combines and incorporates the peculiar structural features of both of said container bodies <NUM>. a and <NUM>.

Said container body <NUM> is defined by a base wall <NUM> wherefrom a plurality of protrusions <NUM> develop and extend, in the form of a side wall, adapted to define a cavity that receives said elastic coupling (i.e., said elastically yielding body <NUM>), in the case of the container body <NUM>. a, or said clamping ring nut <NUM>. b, in the case of the container body <NUM>.

Said projections <NUM> are arranged in the proximity of the outer perimeter of said base wall <NUM>.

The base wall <NUM> is provided with a suitably shaped hole <NUM> in order to releasably couple with the coupling/jointing means <NUM> arranged on said central bush <NUM> (<FIG>).

Such releasable coupling, substantially defined by a shape coupling <NUM>-<NUM>, allows joining said container body <NUM>, <NUM>. b with said central bush <NUM>.

<FIG> show a possible executive variant of a sliding ring nut <NUM>. a provided with a threaded through hole <NUM> and with a plurality of recesses (or seats) <NUM> adapted to couple, preferably by shape coupling <NUM>-<NUM>, with the respective convex portion <NUM> of the projections <NUM> of the container body <NUM>, <NUM>.

Preferably, there may be provided as many recesses <NUM> as the projections <NUM>. Such shape coupling <NUM>-<NUM> allows said container body <NUM>, <NUM>. a to slide on said sliding ring nut <NUM>. a, in particular enables each convex portion <NUM> to slide on the respective recess <NUM>.

The stop ring nut <NUM>. b may advantageously provide a plurality of similar recesses, adapted to couple, preferably by shape, with the convex portion <NUM> of the projections <NUM> of the container body <NUM>, <NUM>.

Such shape coupling <NUM>-<NUM> allows, by acting on said container body <NUM>; <NUM>. b, screwing/unscrewing said sliding ring nut <NUM>. a and/or said stop ring nut <NUM>. b along said shank <NUM>.

Said sliding ring nut <NUM>. a is provided with a guiding and sliding surface <NUM> whereon said elastically yielding body <NUM> moves, so as to provide a static and fixed support to the movement of said elastic coupling, and of an abutment surface <NUM> that acts as an end stop and stop for the movement of said body <NUM>.

Said guide surface <NUM>, inclined of the said angle φ, comprises, integrally or partially, at least one portion of an inclined plane; preferably said guide surface <NUM> comprises at least one portion of a surface inclined relative to the symmetry axis of the ring nut <NUM>. a, preferably convex truncated cone, truncated-pyramid or the like.

<FIG>, <FIG> and 6d show a possible executive variant of said elastically yielding body <NUM>.

Said body <NUM> comprises a sliding ring nut <NUM>. a, a plurality of sliding elements <NUM> maintained in position and joined by one or more elastic opposing means <NUM>, such as for example O-rings, elastic gaskets or the like, also comprised in said elastically yielding body <NUM>.

Each sliding element <NUM> is provided with one or more grooves <NUM> adapted to house said elastic opposing means <NUM>, and with at least one gliding surface <NUM>, advantageously comprising an inclined plane portion, capable of moving along the guide and sliding surface <NUM> of said sliding ring nut <NUM>.

Between said guiding surface <NUM>, which is fixed, and said gliding surface <NUM>, which is capable of moving, a sliding interface is obtained that allows the sliding element <NUM> to slide on the sliding ring nut <NUM>. a; preferably such sliding interface is made by rectilinear surfaces such as to substantially define an inclined plane.

The abutment surface <NUM> acts as an end stop for the sliding of the sliding element <NUM>, preventing it from translating too much hitting the inner walls of the said container body <NUM>.

According to the invention said sliding interface is inclined with respect to the longitudinal axis of said boss by the said angle φ, which allows a retrograde motion, so as to allow, by means of said sliding of the parts, the transformation of the longitudinal (axial) stress generated by said pulling Ft or pressing Fp force into a transverse (radial) stress Fr.

Said radial stress Fr is substantially absorbed and cushioned by the elastic deformation undergone by said elastic means <NUM> and by the sliding of said sliding elements <NUM> along said guide surface <NUM>.

Nothing prevents, in accordance with possible embodiments, from making said elastically yielding body <NUM> in a single element capable of elastically deforming and suitably shaped in order to be able to cooperate with said sliding ring nut <NUM>. a and slide on said guide surface <NUM>.

The boss according to the present invention, see <FIG>, may be obtained by means of a first assembly <NUM>, hereinafter referred to as abutting assembly <NUM>, comprising at least one stop container body <NUM>. b, a clamping ring nut <NUM>. b, an optional washer <NUM>, and a second assembly <NUM>, hereinafter defined as yielding assembly <NUM>, comprising at least one sliding container body <NUM>. a, a sliding ring nut <NUM>. a, the elastically yielding body <NUM>, said first <NUM> and second <NUM> assembly being suitably arranged along said shank <NUM>.

To facilitate the assembly and installation phase, it is possible to pre-couple the various parts that make up the elastic coupling and said abutment assembly <NUM> and yielding assembly <NUM>.

The elastic coupling may be pre-mounted by placing the sliding elements <NUM> on the sliding ring nut <NUM>. a, in particular on the guide and sliding surface <NUM>, and then locking the parts by positioning the elastic means <NUM> (<FIG>). Said elastic means <NUM>, once inserted in the grooves <NUM> provided by said sliding elements <NUM>, are sufficiently tensioned and elongated so as to provide an elastic force capable of retaining and maintaining the parts in position and guaranteeing the mounting thereof, i.e., said elastic force is such as to ensure the assembly of the parts and not allow a reciprocal sliding of the same.

To make and pre-mount the yielding assembly <NUM> the coupling and locking of said sliding ring nut <NUM>. a, provided with the elastic coupling, and of said container body <NUM>. a is carried out by the respective recesses <NUM> and convex portions <NUM>.

In accordance with a preferred variant, there is provided the use of a washer <NUM>, previously inserted in the container body <NUM>, <NUM>. b and arranged on the base <NUM>, adapted to increase the adherence and grip between said base <NUM> and said sliding elements <NUM>.

Said washer <NUM>, therefore, facilitates the transmission of the axial stress between the various components of the yielding coupling, contributing to strongly convert said axial stress Fp into radial stress Fr.

To make and pre-mount the abutment assembly <NUM> the coupling and locking of said clamping ring nut <NUM>. b, devoid of the elastic coupling, and said container body <NUM>. b, is carried out by means of the respective recesses <NUM> and convex portions <NUM> (<FIG>).

Substantially, the abutment assembly <NUM> provides for joining only the clamping ring nut <NUM>. b with only the stop container body <NUM>. b, possibly providing for the previous insertion of a washer <NUM> in the stop container body <NUM>. b and arranged on the base <NUM>, adapted to increase adherence and grip between said base <NUM> and said clamping ring nut <NUM>.

To facilitate the assembly and installation step it is possible to pre-couple, when necessary, the central bush <NUM>, possibly already coupled with the eccentric bush <NUM>, to the container body <NUM>, <NUM>. b of said the abutment assembly <NUM> or yielding assembly <NUM>.

Such pre-mounted assemblies, which can be made previously, facilitate and speed up the installation operations of the panelling, since the operator must provide for inserting, arranging and screwing such assemblies along the shank <NUM>.

With reference to <FIG>, <FIG> and <FIG>, the possible mounting steps and the operation of the system according to the present invention are now described.

By way of an example, the mounting of the boss <NUM> described above, may proceed as follows:.

Such coupling of the parts allows the operator to work safely and comfortably as he/she has reference and anchoring points (shank <NUM> and/or eccentric bush <NUM>) available for positioning the panel <NUM> even before its final fixing.

The panel <NUM>, in fact, once inserted on the eccentric bush <NUM>, does not weigh with its entire weight on the operator.

According to the invention it is preferably provided that each of said panels <NUM> is secured to the shoulder <NUM> by means of one or more upper constraints Pfs aligned along an upper line or array and one or more lower constraints Pfi aligned along a lower line or array.

Preferably each panel <NUM> provides at least two lower fixing constraints Pfi and as many upper ones Pfs.

Preferably the fixing system <NUM> according to the invention provides that one or more of said upper constraints Pfs consists of one of the said bosses <NUM> and/or that one or more of said lower constraints Pfi consists of one of said bosses <NUM>.

In essence, the bosses <NUM> and <NUM> differ from each other in the arrangement of the components, i.e.:.

Such arrangement of the components of the respective bosses <NUM> and <NUM> allows the panel to yield and move under the action of a load F.

Of course, nothing prevents the provision of different or alternative arrangements of the components, as long as they fall within the wording of the appended claims, so as to adapt the bosses to different situations that provide, for example, a direction of the loads different from the one illustrated here.

The impacts that the panels <NUM> may undergo, at least if these form a balustrade or similar type of barrier, exert a force thereon, the component F whereof, orthogonal to them, is directed from the structure <NUM> towards the same panels <NUM>.

Since this force F is eccentric with respect to the said fixing points Pfs and Pfi, two forces, pulling Ft and pressing Fp, respectively, create thereon as well as a torque C.

According to the invention, each upper constraint Pfs is such as to yield elastically to a pulling force Ft in as well as to a torque C and likewise each lower constraint Pfi is such as to yield elastically to a pressing force Fp as well as to the same torque C, the barrier consisting of panels <NUM> may yield elastically to said impacts of force F.

When a force F hits the panel <NUM>, said panel rotates with respect to the constraining point provided by the bosses <NUM> and <NUM> and presses axially (longitudinally) on the respective container bodies <NUM>. a which enclose the relative elastic couplings.

This axial (longitudinal) thrust, by means of the base <NUM> of said container body <NUM>. a and possibly said washer <NUM>, transfers to the sliding elements <NUM> that begin to slide along the guide and sliding surface <NUM> of the sliding ring nut <NUM>.

Said sliding ring nut <NUM>. a, being screwed and constrained on the shank <NUM>, cannot move and is therefore able to provide a stable and fixed surface for the sliding of said sliding elements <NUM>.

In order to be able to move, said sliding elements <NUM> must be able to oppose the elastic force exerted by the elastic means <NUM>, said elastic force being won by said axial force that deforms the said elastic coupling.

As anticipated, therefore, said elastic coupling is capable of transforming and converting the axial (longitudinal) stress generated by said pulling Ft or pressing Fp force to a radial (transverse) stress Fr, said radial (transverse) stress Fr being absorbed and cushioned by the elastic deformation of said elastic means <NUM> and by the sliding of said sliding elements <NUM> along said guide surface <NUM>.

Preferably, by appropriately choosing the elastic rigidity of the elastically yielding body <NUM> and/or of the elastic means <NUM>, depending on the applied forces Fa and predictable torques C and the clearance provided between the eccentric bush <NUM> and the through holes <NUM> of the panel <NUM>, the boss <NUM>, <NUM> may rotate, up to an angle α of <NUM>° (where α is the angle comprised between the lying plane of the shoulder <NUM> and the lying plane of said panel <NUM>).

Such bosses <NUM> and <NUM>, besides yielding elastically, also support the elastic recovery of the panel with a rotation direction opposite to the previous one by an angle β < α and so on until the cushioning of the oscillations.

Nothing prevents, although not shown in the figures, that the fixing system <NUM> further provides, for example at the height of the upper constraints Pfs, with the cushioning means for dissipating the impact energy transmitted by the force F. Even more advantageously, such cushioning function may be integrated in the same upper and/or lower constraints Pfs, Pfi and even more advantageously, the same bosses <NUM>, <NUM> may integrate means providing a cushioning function.

Furthermore, the same elastic means <NUM> may consist of a material having a gradual and slowed-down elastic recovery, and therefore able to offer a cushioning effect to the boss <NUM>, <NUM>.

This feature, besides the transformation of the stress from axial to radial, allows reducing the longitudinal dimensions of the boss <NUM>, <NUM> according to the present invention.

The boss according to the present invention provides small longitudinal dimensions since the means that absorb and oppose the mechanical stress do not work along the longitudinal axis of said boss, but operate radially by means of said transformation of the stress.

The cushioning function obviously means the ability of well-known mechanical members to easily support a movement imparted to an element and then allow, but more slowly, returning to the initial position by dissipating wholly or partly the elastic energy that has been absorbed.

Claim 1:
Elastic boss (<NUM>; <NUM>) for the elastic fixing of one or more panels (<NUM>) to a shoulder (<NUM>) of a support structure (<NUM>), in particular for the installation and the elastically yielding support of balustrades, parapets, barriers or similar architectural elements of any material and shape, said boss suitable for being anchored to said shoulder (<NUM>) by a shank (<NUM>) intended to be irremovably fixed to said structure (<NUM>);
wherein it comprises an elastically yielding body (<NUM>) comprising:
- at least one sliding element (<NUM>) whereon said panel (<NUM>) can press;
- at least one sliding surface (<NUM>), whereon said sliding element (<NUM>) is capable of sliding, irremovably constrained to said shank (<NUM>) and intended to be inclined with respect to the lying plane of the panel (<NUM>) at rest by an angle φ such as to allow the retrograde motion of the sliding element (<NUM>) sliding on the sliding surface (<NUM>);
- elastic opposing means (<NUM>), positioned and constrained so as to be able to exert an elastic force (Fe) that insists on said sliding element (<NUM>) so as to press it on said sliding surface (<NUM>);
said elastically yielding body (<NUM>), by means of said sliding element (<NUM>), sliding surface (<NUM>) and elastic opposing means (<NUM>), being capable of opposing yields caused by a load F substantially orthogonal to the lying plane of the panel (<NUM>) with an elastic reaction force (Fe) substantially parallel to the lying plane of the said panel (<NUM>).