ITTO20060320A1 - EXPANSION JOINT FOR FLOORING ELEMENTS AND RELATIVE ASSEMBLY AND ASSEMBLY METHOD - Google Patents

Description

Description of the Industrial Invention entitled: "EXPANSION JOINT FOR FLOORING ELEMENTS AND METHOD OF CONSTRUCTION AND RELATIVE ASSEMBLY"

TECHNIQUE SECTOR

The present invention relates, in general, to expansion joints to be used to join pavement elements for roads, bridges, viaducts, airport runways, parking areas and similar structures. In particular, the present invention relates to expansion joints configured to connect pairs of flooring elements, consisting for example of concrete slabs covered with bituminous material, so as to compensate for any deformations of the flooring elements due, for example, to variations thermal.

NOTE ART

It is known that the pavement elements for roads, bridges, viaducts, airport runways, parking areas and similar structures, which hereafter, for simplicity, will be referred to as pavement or infrastructure elements or infrastructures are subject to thermal deformation and that the joint, generally between pairs of flooring elements, is made with expansion joints, ie joints which have the characteristic of adapting elastically to the mutual deformation of the flooring elements.

For example, expansion joints are known from the patent publications GB_1439157 and GB_1510622 having the characteristic of adapting elastically to the mutual deformation of the flooring elements.

Known joints comprise elastic material, for example rubber configured in various ways to compensate for the deformations of the flooring elements, and metal reinforcement or anchoring elements positioned at the ends of the joints; each reinforcement element generally comprises at least one anchoring slot to allow anchoring, by means of suitable bolts associated with the flooring and reinforcement elements, the expansion joints to the respective concrete slabs of the flooring elements.

According to the known art, the reinforcement elements generally have an "L" -shaped section and are completely included or embedded in the elastic material.

The preferred solution of drowning the reinforcement elements in the elastic material is on the one hand dictated by the need to protect the reinforcement elements from corrosion due to external agents, such as humidity, corrosive gases or liquids, etc. and on the other hand it is based on the preconception that there is no technical advantage in putting the reinforcement elements in contact with the pavement elements.

In reality, the Applicant has found that the known solution of drowning the reinforcement elements in the deformable elastic material involves a series of problems.

First of all, the anchoring slots and bolts (nuts, washers and rods) are in any case subject to corrosion phenomena, as they are not protected in any way.

Furthermore, the interposition of the rubber between the metal reinforcement elements, for example steel, and the concrete slab, makes the whole joint structure not sufficiently integral with the body of the same flooring element, causing a loosening of the joint and consequently its deterioration.

In summary, the Applicant has found that the set of corrosion phenomena of the anchoring areas and of low rigidity in the connection between the joint and the infrastructures are capable of causing premature loosening of the bolts which fix the joints to the flooring elements. This phenomenon makes it necessary, as easily understood, to resort to frequent extraordinary maintenance of the expansion joints and the consequent interruption of any use of the joints and flooring elements involved.

The above problem is particularly relevant since, in most cases, the expansion joints are used on infrastructures, such as roads, motorways, railway passages of particularly intense use, so any maintenance with consequent interruption, even partial, of the In addition to maintenance costs, the use of such infrastructures also leads to costs in terms of inconvenience or non-use.

DESCRIPTION OF THE INVENTION

Therefore, the object of the present invention is a road expansion joint which allows to avoid the above mentioned problems of frequent extraordinary maintenance of the expansion joints.

The object of the present invention is also a manufacturing and assembly method which drastically increases the reliability of the assembled joints over time.

The purpose is achieved by the expansion joint to be used to join pavement elements for roads, bridges, viaducts, airport runways, parking areas and similar structures as claimed. The present invention also relates to a method for making and mounting the expansion joint of the present invention.

The claims form an integral part of the technical teaching provided herein about the invention.

According to a preferred embodiment, the expansion joint of the present invention comprises at least one elastic element and reinforcement or anchoring elements in composite material, resistant to corrosion, fixed externally to the elastic element.

In accordance with a further characteristic of the present invention, the anchoring elements comprise an external anchoring surface adapted to be rigidly anchored to a corresponding anchoring surface present in the infrastructures to be joined.

In accordance with yet another characteristic of the present invention, the anchoring between the joint and the infrastructure is carried out by interposing a resin with an adhesive function between the anchoring elements and the infrastructure.

BRIEF DESCRIPTION OF THE FIGURES

This and other characteristics of the present invention will become clear from the following description of preferred embodiments, made by way of non-limiting example with the aid of the attached drawings, in which elements indicated with the same or similar numerical reference indicate components which have the same or similar functionality and construction and in which:

Fig. La represents a first embodiment of the expansion joint according to the present invention;

Fig. 1b represents the first embodiment of the joint of Fig. 1, in use;

Fig. 2a represents a second embodiment of the expansion joint according to the present invention, in use; And

Fig. 2b represents a variant of the second embodiment, in use.

DESCRIPTION OF A PREFERRED FORM OF PRODUCTION

The following description describes two embodiments of expansion joints with the simple purpose of illustrating possible variants of these joints as the amount of expansion sustainable by the joints themselves varies when in use.

Of course, the examples described cannot be exhaustive of all possible embodiments.

With reference to Fig. La, in a first embodiment, an expansion joint (joint) 10 for paving elements (infrastructures) 20 (Figs. La, 1b) comprises an elastic element 11, and, preferably, at least one pair of anchoring elements or elements of reinforcement 12 fixed to the elastic element 11 and able to allow anchoring by means of suitable fastening elements 15, for example bolts, the joint 10 to at least one pair of flooring elements 20.

According to this first embodiment of the joint 10, the elastic element 11, for example made of rubber, comprises, in two areas opposite the ends of the joint 10, respective coupling elements 111 having one or more cavities 112 configured to house the fastening elements (bolts) 15 having, for example nuts 151, washers 153 and threaded rods 155, suitable for fixing, in a known way, the joint 10 to the flooring elements 20. The elastic element 11 further comprises, in a central zone thereof, a deformation element 114, for example an element with a sawtooth section having a certain width "1" at rest; the deformation element 114 is configured in such a way as to be able to modify, in use, the width "1", as the dimensions of the paving elements 20 vary in the direction of the width "1" and thus withstand the deformations of the infrastructures 20.

The anchoring elements 12, respectively, in the various preferred embodiments, have an "L" -shaped section, are integrally glued or fixed to the base of the two hooking elements 111 and have external visible surfaces 12a. Even more preferably, the outer surface 12a of the anchoring elements 12 is configured so that, in use, it is in close and rigid contact with the infrastructure 20 following the anchoring or fixing of the joint 10 to the infrastructure 20 itself, such as will be described in detail later. The anchoring elements 12 each comprise at least one slot 121 in correspondence with the cavities 112 and, preferably, are fixed to the elastic element 11, in a known way, by molding and vulcanization.

Each anchoring element 12 is able to cooperate, with the threaded stems 155, for example fixed in a known way to the respective flooring elements 20, so as to allow the joint 10 to be anchored with the nuts 151 and the washers 153 to the flooring elements 20 .

According to a second embodiment, the joint 10 comprises an elastic element 110 (Figs. 2a and 2b), also preferably made of rubber, and, in addition to a pair of anchoring or armature elements 12 with shape and characteristics equivalent to those already described for the first embodiment, further reinforcement elements, 120a, 120b and 120c, suitable at least to reinforce the joint 10, as will be described in detail below.

According to this second embodiment, the elastic element 110 comprises two hooking elements 111, equivalent to those already described in the first embodiment, and, on a first face, for example the upper face of the elastic element 110, one or more intermediate elements, for example in Fig. 2a and 2b, three upper intermediate elements (upper elements) 115a, 115b and 115c, separated, in the example, by four upper recesses 115 of width "Is", for example of shape triangular. The elastic element 110 also comprises, on a second face, for example the lower face, one or more lower intermediate elements, for example in Fig. 2a and 2b, a lower intermediate element 118c, separated, in the example, from the hooking 111 by means of two lower recesses 118 of "li" width, for example triangular in shape.

The upper recesses 115 and lower 118, as easily understood by a person skilled in the art, are able to cooperate to modify the widths "ls" and "li" as the dimensions of the infrastructures 20 vary in the direction of the widths "ls" and "li" and thus withstand the deformations of the infrastructures 20.

According to the example of Fig.2a and 2b, the upper elements placed at the end of the joint 10, 115a and 115b respectively, comprise, respectively, the upper reinforcement elements (upper reinforcement), 120a and 120b, while the element lower intermediate 118c comprises the lower armature element 120c.

In particular, in the example of Fig. 2a the upper reinforcement elements, 120a and 120b, and lower, 120c, are provided embedded in the elastic element 110, while in the example of Fig. 2b the upper reinforcement elements, 120a and 120b, and lower, 120c, are provided, a configuration which in the Applicant's opinion is preferable, fixed or glued to the elastic element 110 so that it remains exposed on the upper face, and in particular, on the lower face, the surface of the reinforcement elements , 120a, 120b, 120c.

Naturally, also in this embodiment the armature elements 120a, 120b, 120c are fixed to the elastic element 110, preferably, in an equivalent way to what has already been described, ie by molding and vulcanization.

The reinforcement elements 120a, 120b, 120c are suitable, in both the described configurations, as easily understood by a person skilled in the art, to give strength to the joint so that it does not break or bend as a result of mechanical stresses due to moving loads on the joint itself.

In all embodiments, all the reinforcement elements or at least the anchoring elements 12 are made of composite material, for example material resulting from the coupling of substances such as:

- reinforced thermosetting polymer, e

- glass fiber or other type of fiber

- reinforced thermoplastic polymer, e

- glass fiber or other type of fiber.

In the preferred embodiment, the composite material is shaped by hot molding starting from a basic composite material made with the above substances.

Advantageously, this composite material has the peculiar characteristic of guaranteeing very high mechanical resistance to the armature elements, for example at least equivalent to the metal material, and high resistance to corrosion due, for example, to external agents, such as humidity, corrosive gases or liquids, etc. .

Of course, according to further embodiments, the composite material can also be obtained by coupling other materials together, but, according to the preferred embodiment, it is advantageous for it to have the characteristic of guaranteeing very high mechanical strength, for example at least equivalent to metal material, and high resistance to corrosion due to external agents, such as humidity, corrosive gases or liquids, etc.

In the following description, the reference to a composite material for the realization of at least the anchoring elements, should be understood as referring to a composite material with the characteristics indicated above.

Each of the infrastructures 20 to which the joint 10 must be anchored comprises, at the ends to be joined, for example, a concrete slab (slab) 21 having a visible surface 21a, configured for anchoring the joint 10, and a threaded rod 155 fixed to the slab 21 and suitable to allow the joint to be fixed to the slab. The infrastructure 20 also comprises, in the embodiments described, outside the positioning zone of the joint 10, layers of bituminous carpet, for example two layers 22a and 22b, known per se, having different characteristics in terms of finish and quality.

Preferably, between the infrastructures 20 to be joined there is also inserted, fixed in a known way to the infrastructures 20 themselves, a gasket or flashing 18, generally made of rubber, suitable for allowing the flow of water, for example rainwater, along the positioning of the joints. .

The anchoring or installation of the joint 10, for example to a pair of infrastructures 20, is operated as follows.

In a first step, resin 28 is preferably spread, for example anti-shrink resin, of a known type, on the surface 21a of the insole 21. This resin has, preferably, the purpose of acting as an adhesive between the joint 10 and the infrastructure 20 as well as the purpose to help keep the contact surface between the anchoring elements 12 and the slab 21 leveled.

Of course, in other embodiments the surface 21a of the slab 21 can be obtained smooth enough, for example by the use of fresh cement, to allow a direct anchoring of the joint to the slab without the use of resin.

In a second phase the joint 10, having inserted the threaded rods 155 into the slots 121 of the joint, is anchored by means of the washers 153 and the nuts 151 to the pair of infrastructures 20. In this phase the nuts 151 and the washers 153 are tightened with the force necessary to ensure that the joint 10 and the infrastructure 20 are rigidly joined together.

Finally, in a third step the cavities 112 corresponding to the position of the bolts 15 and any interstitial areas 113 between the layers of bituminous carpet, 22a and 22b, and joint 10 are filled with sealing material, for example two-component resins of a known type.

Thanks to the method of making the joint 10, and the installation method described above, the anchoring elements 12, having the external surface 12a exposed externally to the base of the joint 10, come into direct contact with the surface 21a of the concrete slab 21 and rigidly fixed thereto, with the possible contribution of the resin 28, if present, so that the joint 10 and the slab 21 form a particularly rigid and solid connection and substantially form a single body.

In fact, contrary to what is foreseen in the known art, a rigid connection is obtained without any interposition of elastic material between the surfaces of the anchoring elements and the slab, or, in other words, between the joint and the infrastructure. Furthermore, since the anchoring elements are made of composite material, there is no risk of corrosion of the anchoring elements. Naturally, the joint 10, thanks to the presence of the elastic element, maintains its elasticity characteristics unaltered, suitable for withstanding the deformations of the infrastructure.

In the second embodiment, or in general embodiments similar to it, the reinforcement elements 120a, 120b, 120c (Figs. 2a, 2b) are preferably made of composite material and fixed externally to the elastic element 110 .

In these embodiments, the reinforcement element or elements, if fixed externally to the base of the joint, have an external surface capable of coming into contact with the visible surface 21a of the slab and contribute to giving rigidity to the connection between the infrastructure. and joint, favoring the operation of the elastic element 110 of the joint and in any case presenting no risk of corrosion.

In summary, in the Applicant's opinion, the joint 10 described, both in the first embodiment and in the second embodiment, allows to obtain, once installed, a surprising technical result since by making the connection between the joint and the infrastructure more rigid, it prevents loosening of the bolts and consequently significantly lengthens the maintenance intervals.

The expansion joint has been described in two embodiments. Of course, the embodiments of the joint can be multiple as well as the shapes of the elastic element suitable for compensating for the deformations of the infrastructures to be joined.

In particular, the shape of the elastic element can be diversified, as easily understood by a person skilled in the art, according to the extent of the deformations that the joint must withstand, without thereby departing from the scope of what is described and claimed.

Correspondingly, the shape of the infrastructures in their terminal parts can be different from that described as well as the method of fixing the joint to the infrastructures, without thereby departing from the scope of what is described and claimed.

Furthermore, the reinforcement elements present in the joint can be combined in various ways. For example, the anchoring elements 12 and the reinforcement elements, arranged to come into contact with the slabs of the infrastructures, can be made of composite material, while the reinforcement elements of pure reinforcement and, preferably, drowned in the elastic element, they can be made of metal material.

Obvious modifications or variations are possible to the above description, in the dimensions, shapes, materials, components and connections, as well as in the details of the illustrated construction and method of operating without departing from the spirit of the invention as set out in the following claims.

Claims (12)

CLAIMS 1. Expansion joint for connecting pavement infrastructures (20) comprising at least one elastic element (11, 110) having at least two lateral attachment elements (111), - at least two anchoring or reinforcement elements (12) each fixed to a corresponding coupling element (111) and configured to be anchored to respective anchoring surfaces (21a, 28) of said infrastructures (20), characterized by what - said at least two anchoring elements (12) - are made of composite material, they are fixed to said coupling elements (111) so as to present at least one visible surface (12a) capable of being rigidly anchored in direct contact with said anchoring surfaces (21a, 28) of said infrastructures (20). 2. Expansion joint according to claim 1 characterized in that said anchoring elements (12) made of composite material have mechanical strength equivalent to that of anchoring elements made of metallic material and are resistant to corrosion due to external agents. 3. Expansion joint according to claim 1 or 2 characterized in that said anchoring elements (12) made of composite material are obtained by molding materials comprising the coupling of substances selected from the groups formed by - at least reinforced thermosetting polymer and glass fiber or other type of fiber, or - at least epoxy resins and glass fiber or other type of fiber. 4. Expansion joint according to one of the preceding claims characterized in that said at least two anchoring elements (12) each comprise - at least one slot (121) configured to allow fixing of the joint (10) to said infrastructures (20) by means of bolts (15). 5. Expansion joint according to one of the preceding claims characterized in that said elastic element (11) comprises at least one deformation element (114, 115, 118) interposed between said two lateral coupling elements (111). 6. Expansion joint according to one of the preceding claims characterized in that it comprises one or more further reinforcement elements (120a, 120b, 120c) which are made of composite material, are fixed to said elastic element (11, 110) and are able to give strength to said joint (10). 7. Expansion joint according to one of the preceding claims characterized in that said anchoring surfaces (21a, 28) of said infrastructures (20) comprise at least one surface (21a) of a concrete slab (21). 8. Expansion joint according to any one of claims 1 to 6 characterized in that said anchoring surfaces (21a, 28) of said infrastructures (20) comprise at least one surface (21a) of a concrete slab (21), and from what said visible surface (12a) of the anchoring element is glued to said surface (21a) of said slab (21) by means of a resin (28) interposed between said visible surface (12a) and said surface (21a) of said slab (21). 9. Method for making an expansion joint to be anchored to anchoring surfaces (21a, 28) of paving infrastructures (20), characterized by the providing at least one elastic element configured to be hooked to said infrastructures (20) by means of at least two lateral hooking elements (111), - prepare at least two anchoring or reinforcement elements (12) in composite material, - fixing said anchoring elements (12) to said coupling elements so that said anchoring elements have a visible surface (12a) capable of being rigidly anchored in direct contact with said anchoring surfaces (21a, 28) of said infrastructures (20). 10. Method according to claim 9 characterized in that said step of providing at least two anchoring or reinforcement elements (12) in composite material comprises the step of - molding materials comprising the coupling of substances selected in the groups formed by at least reinforced thermosetting polymer and glass fiber or other type of fiber, or at least epoxy resins and glass fiber or other type of fiber. 11. Method according to claim 9 or 10 characterized by the further step of - anchor said joint to said infrastructures. 12. Method according to claim 11 characterized in that said step of anchoring said joint to said infrastructures comprises at least the steps of - spread resin with an adhesive function on said anchoring surface (21a) of said infrastructure, - anchoring said visible surface (12a) of said anchoring element (12) to said anchoring surface (21a) of said infrastructure (21) by means of said resin (28).