IT202100028355A1 - Improved rib for supporting and consolidating an excavation, and method of installing such a rib within an excavation - Google Patents

Description

DESCRIPTION of the industrial invention entitled: "Improved rib for the support and consolidation of an excavation, and method for installing such a rib inside an excavation"

Field of invention

The present invention concerns an improved rib for the support and consolidation of an excavation and a method for installing a support rib within an excavation.

Technology background

In the field of support structures? known to use structural elements that are connected to each other to create the final shape of the support structure itself. These structural elements can have an open section, for example C-shaped, double T, or closed. In the case of closed sections, the structural elements are tubular and can have sections of any shape, for example circular, square, rectangular or triangular.

For the support of excavations, such as motorway or railway tunnels,? known to use consolidation arches called ribs. In particular, a hundred usually includes a plurality? of shaped steel structural elements connected to each other in a vaulted configuration. These elements are made up of open profiles with an H, INP, C or double T cross section and are made integral with each other via a connecting element called a clamp. In most cases, the profiles are connected to each other in correspondence with the excavation to be consolidated, after having been shaped in carpentry. After its assembly, each rib is ? connected to adjacent ones through connecting chains whose ends? they hook onto supports welded along the body of the rib profiles. The space between two consecutive ribs and the excavation wall is usually consolidated using sprayed concrete (spirtz-beton).

To connect two structural elements together and obtain the final shape of the support structure, a pair of junction plates intended to be mutually connected through bolts are usually used. A joint system? known from document EP 2354447, which describes a support and consolidation support for an excavation made up of several? structural elements connected to each other. In the known joining system, each first joining plate has portions which are welded to a relevant structural element at an end section. Each joint plate, usually rectangular in shape, includes two sets of holes for connecting bolts that secure the plates together creating the connection between the structural elements so that the structural elements form a continuous structure that develops throughout the extension of the structure. This known joint system presents several drawbacks, why? for example, the structural elements must be positioned precisely in relation to each other so as to align the holes in the plates into which the bolts are inserted. This is difficult, in particular in the case of rather extensive structures, especially vertical ones, or which must take on particular final shapes, such as for example the ribs which have a vaulted conformation. Furthermore, the connection cannot? be carried out automatically as the mutual positioning of the plates and the insertion of the bolts can? be made only manually. This connection therefore requires a considerable amount of time. Furthermore, this connection can be unstable if, for example, the bolts are not fixed correctly. In particular the instability? of the connection can? increase over time if the tightness of the bolts is not checked periodically.

To solve the above problems, the present applicant has developed the solution described in WO 2015/186029 which provides an articulated connection system with automatic locking of the structural elements that make up a support and consolidation rib which has a vaulted configuration that generally recalls that of the portion of excavation intended to be consolidated through the arch itself. The structural elements that make up the rib, made of metallic material such as construction steel, are connected to each other with a rotary coupling, for example by means of hinges, so as to pass from a first position in which the structural elements are substantially folded into each other on the other to a second position in which they are arranged to form at least a substantially continuous portion of the rib.

The system described in WO 2015/186029 is ? proven effective, but has characteristics that limit its use. The final position of the rib, and in particular of the two lateral feet, is not ? defined precisely and it could happen that adjacent ribs are not perfectly aligned with the base of the excavation vault, resulting in non-homogeneity? in the resulting gallery wall. Furthermore, the thrusts exerted by the excavation wall on the rib near the base of the excavation can deform or even move the position of the feet of the rib, with consequences that need to be remedied with tunnel maintenance operations.

There is therefore a need for a rib with improved characteristics, which constitutes an improvement compared to the known rib described above.

Summary of the invention

Purpose of the present invention? therefore that of obtaining a rib for the support and consolidation of an excavation which allows for a quick and safe connection between its structural elements, such as to be particularly stable when installed inside an excavation. Another purpose? that of obtaining a relatively cheap and simple to manufacture rib. Another purpose? that of obtaining a curtain wall that can be installed quickly and automatically.

These and other purposes are achieved by means of a pre-assembled rib comprising several? structural elements connected mobile to each other so that the rib can move from an initially restricted configuration before installation to a definitive configuration of support and consolidation of the internal profile of the excavation.

An advantage of the present invention? the fact that it allows the immediate and integrated consolidation not only of the walls but also of the bottom of the tunnel, through a section of the so-called "inverted arch" or "strut", which is also part of the structural elements connected to each other in a mobile way, and such that it can be locked in position when the curtain? in the final configuration, thus allowing the installation of the curtain at the same time as installation, obviating the need? to operate in subsequent installation phases.

According to a first aspect, a rib is described for the support and consolidation of an excavation. The center can? understand more? structural elements. Structural elements can be connected to each other. The structural elements can be movably connected to each other. The connection between the structural elements can? be such that the curtain can? move from a pre-assembled configuration before installation to a definitive installation configuration. The pre-assembled configuration can be at least partially folded. In the final configuration the structural elements can be blocked with respect to each other. Can the structural elements be continuously blocked? structural, i.e. resisting the forces exerted by the walls of the excavation as if they were a single element or as if they were blocked with fixed connection members such as bolts and the like. The structural elements can be locked in a mutual position which overall defines a rib with a closed geometric profile, or a rib with an arched profile.

According to a particular aspect, the structural elements can be mounted articulated, articulated or oscillating with respect to each other. The structural elements can be connected to each other by means of joint members which include hinges.

According to another particular aspect, a basic structural element, having the function of a strut or inverted arch, can have one?extremity? mounted sliding on a different structural element, lateral to the excavation. According to another particular aspect, the curtain can? include at least three structural elements, preferably at least four or five structural elements, even more? preferably exactly three or exactly four or exactly five structural elements.

According to another particular aspect, a basic structural element, with the function of a strut or inverted arch, can have one or two end connectors? for connection in one or two seats made on one or both lateral structural elements of the rib. In this way ? It is possible to definitively install an arch-shaped rib in the excavation, and subsequently complete it by adding the underlying structural element, which creates the strut or inverted arch and allows the overall structure of the rib to be closed, creating a closed geometric profile. According to a variant, the strut or inverted arch can? can also be installed separately, immediately after installing the arched rib, i.e. the rib elements that form the sides and the vault. The connection of the underlying structural element, i.e. the strut or inverted arch, can happen quickly, immediately or separately, even after a certain time compared to the arched rib structure, also thanks to the possibility? that one or both end connectors? are made orientable, for example using one or two ball joints, which therefore are not affected by any torsions or rotations of the arched rib and its lateral structural elements with respect to the installation plane of the bottom structural element.

According to another aspect, a rib is described in which a basic structural element, acting as a strut or inverted arch, can be made in two distinct portions. The two portions of the bottom structural element can be articulated to two respective lateral structural elements of the rib. The two portions of the bottom structural element can be joined together by means of a junction member. The junction member that joins the two portions of the bottom structural element can be of the snap type to obtain this? a definitive and irreversible configuration of a curtain wall with a closed geometric profile.

According to another particular aspect, a rib is described in which one or more? of the structural elements can be divided into two or more? sections between which corresponding elastic joints can be inserted. The elastic joints allow the thrusts that may be exerted by the walls of the excavation on the rib to be absorbed by reacting elastically.

According to another aspect, a method for installing a rib within an excavation is described. The method can understand the phase of preparing more? structural elements of a rib. The method can understand the phase of connecting said structural elements to each other to obtain a pre-assembled rib. Can the connection? be a mobile link. The method can understand the step of folding the curtain, preferably at least partially, before its installation. The method can understand the phase of transporting the rib, preferably at least partially folded, inside the excavation. The method can understand the phase of installing the rib in a definitive installation configuration in a reciprocal position which overall defines a rib with a closed geometric profile or an arched profile. Preferably in this phase the structural elements can be blocked continuously? structural with respect to each other. According to another aspect, the method can? ensure that the structural elements are blocked in relation to each other in an irreversible manner.

Brief description of the drawings

Further characteristics and advantages will emerge from the following detailed description of a preferred form of implementation, with reference to the attached drawings, given by way of non-limiting example, in which:

- figure 1? a schematic view of the cross section of an excavation within which? post a first example of a curtain which incorporates elements of the present invention, in a configuration prior to definitive installation;

- figure 2? a schematic view of the same excavation section as figure 1, with the arch in an almost identical configuration. definitive, which provides integral support for the entire section of the excavation;

- figure 3? a perspective view of an example of the construction of a foot of the rib;

- figure 4? a front view of another example of the construction of a foot of the rib;

- figure 5? a side view according to arrow V of figure 4;

- figure 6? a perspective view of an example of an articulated connection between two structural elements of the rib;

- figure 7? a section according to the plane of trace VII-VII of figure 6; - the figure 8? a perspective view of an example of connection between two ends? not articulated of two structural elements of the rib, for example between the end? of the strut and the extremity? of a lateral element of the rib;

- figure 9? a view of the connection in figure 8, in the connected configuration in which the two ends? of the structural elements of the curtain wall are blocked against each other;

- figure 10? a detail view of the extremity? of one of the structural elements of figures 8 and 9, for example the extremity? of the strut;

- figures 11 and 12 show a side view of two phases of the connection between the two structural elements of figures 8 and 9, respectively in a configuration not yet connected, and in a connected configuration corresponding to that of figure 9;

- figure 13 shows an example of an elastic joint between two sections of a structural element of the arch, intended to absorb and counteract the deformations of the tunnel wall over time;

- figure 14? a longitudinal section of the elastic joint of figure 13; - figure 15? a perspective view of a variant of the articulated connection between two structural elements of the rib, which can be used as an alternative to the articulated connection of figure 6;

- figures 16 and 17 show a side view of two configurations of the articulated connection, respectively in the not yet connected configuration of figure 15, and in a connected configuration;

- figure 18? a perspective view of another variant of the articulated connection between two structural elements of the rib, in a connected configuration;

- figure 19? a perspective view of an example of connection between two adjacent ribs, also called ?chain? in the field;

- figure 20? a perspective view of another example of connection between two adjacent ribs, also called ?chain? in the field;

- figure 21? a schematic front view of another example of a rib providing integral support for the entire section of the excavation, incorporating elements of the present invention;

- figure 22? a perspective view of a connection between two structural elements of the rib of figure 21, for example between the end? of the lower strut and the end? of a lateral structural element;

- figure 23? a perspective view of the extremity? of one of the two structural elements of figure 22, for example the lower strut;

- figure 24? a perspective view of a connection variant between two structural elements of the rib of figure 21, for example between the extremity of the lower strut and the end? of a lateral structural element;

- figure 25? a schematic front view of another example of a rib which provides integral support for the entire section of the excavation, incorporating elements of the present invention.

Detailed description

The following implementation examples describe characteristics that allow the invention to be implemented. The characteristics described can be variously combined with each other, and are not necessarily limited to the precise embodiment to which the drawings and the related description refer. In other words, a technician expert in the sector who reads the following description will know obtain useful information to know how to achieve one or more? of the characteristics described by combining it with one or more? of the other characteristics described, without the particular wording of the description, paragraphs, sentences or drawings constituting a limit to the possibility? to isolate one or more? of the characteristics described and illustrated in order to combine them with one or more? of any of the other characteristics described and illustrated. More? in detail, in this description any combination of any two expressly described characteristics must be understood as expressly described, even if said characteristics are individually extracted from the specific context in which they can be combined or combined with other, different characteristics, taking into account the skills and knowledge of an expert technician in the sector who understands the possibility? to functionally combine said characteristics without requiring the functional contribution of the other, different characteristics. Unless otherwise specified, each and every element, organ, means, system, component, object described and illustrated in this description must be considered individually described and independently modifiable, as well as separable from and/or combinable with any and all other elements, organs, means, systems, components, objects described and illustrated. The materials, shapes and functions described and illustrated are not restrictive of the present invention, but are only specified to enable an expert technician to understand and implement the invention according to preferred but not exclusive in production.

Referring now to figures 1 and 2, ? schematically illustrated is a cross section of an excavation S, for example the section of a motorway or railway tunnel. The excavation includes a vault V and a bottom F. The bottom F? composed of two flat lateral areas M, with the function of supporting the rib structure, and a central arched area C, which forms the so-called "inverted arch" or "strut". In the following, the two terms will be used interchangeably to indicate the same curtain element.

Inside the excavation S ? illustrated is a support and consolidation rib 10 incorporating aspects of the present invention. In figure 1 the rib 10? shown in a configuration prior to final installation. In figure 2 the rib 10? illustrated in a configuration close to final installation. In particular, the rib 10? completely extended so as to occupy the entire circumferential development of the excavation S, and one of its lateral feet, in particular the foot illustrated on the left in figure 2, is already? elongated so as to rest on the corresponding left lateral M flat area. The foot of the bow shown on the right in figure 2? instead still in the retracted position. Following the extension of the foot of the rib on the right in figure 2 resting on the corresponding flat lateral area M on the right, the definitive positioning configuration of the rib for the support of the excavation section S is obtained.

The rib 10? made up of more structural elements, for example four structural elements 11, 12, 13, 14. The structural elements 11, 12, 13, 14 are preferably made of metallic material, such as for example construction steel (Fe 430 or other). According to a preferred embodiment, each structural element 11, 12, 13, 14? formed by a body made up of a profile with an open cross section, for example H or C or double T, for example a European standardized profile such as HEA, HEB, HEM, IPE, etc. Not ? However, it is excluded that one or more? of the structural elements 11, 12, 13, 14 are made with different profiles, for example tubular profiles with circular, elliptical, square, rectangular section, etc. In particular, right? excluding that the structural element 14, which forms the bottom (or "inverted arch") of the rib 10, has a different section from the other structural elements 11, 12, 13 which form the sides and the top? of the rib 10 and which preferably have identical profiles.

The rib 10 has a vaulted configuration symmetrical with respect to a symmetry plane P, defined by one or more? structural elements, for example the three structural elements 11, 12, 13, which form the sides and the top? of the rib 10, and an inverted arch at the bottom, defined by one or more? structural elements, for example from the single structural element 14 or, as will be seen? below with reference to figure 12, from the two structural elements 14a, 14b. The symmetrical vaulted configuration of the rib 10, in the almost definitive shown in figure 2, generally reproduces the section of the portion of the excavation S intended to be consolidated through the arch itself.

The rib 10 illustrated in the figures includes a first lateral structural element 11, a central structural element 12, connected to the first lateral structural element 11, a second lateral structural element 13 connected to the central structural element 12, and a bottom structural element 14 connected to the second lateral structural element 13. As illustrated, the first lateral structural element 11 and the second lateral structural element 13 are arranged in a substantially mirror-like position with respect to the symmetry plane P of the rib 10. In other words, in this example configuration of the rib 10, the first lateral structural element 11 and the second lateral structural element 13 are lateral structural elements of the rib 10. The central structural element 12 and the bottom structural element 14 preferably develop symmetrically between the first lateral structural element 11 and the second lateral structural element 13 with respect to the same plane of symmetry, on opposite sides with respect to a horizontal plane T intersecting the first structural element 11 and the second lateral structural element 13. In the example of the rib 10, the central structural element 12 ? an upper structural element, also called ridge or top structural element, while the bottom structural element 14 is a lower structural element, also called basic structural element or ?inverted arch?.

The first lateral structural element 11 has a first end? 111 operationally connected to a first end? 121 of the central structural element 12. The connection between the first end? 111 of the first lateral structural element 11 and the first end? 121 of the central structural element 12? achieved through first junction organs 151. In proximity? of a second extremity? 112 of the first lateral structural element 11? a first support element 161 of the rib 10 is provided which incorporates and defines a foot of the rib.

Similarly to the first lateral structural element 11, the second lateral structural element 13 has a first end? 131 operationally connected to a second end? 122 of the central structural element 12. The connection between the first end? 131 of the second lateral structural element 13 and the second end? 122 of the central structural element 12? realized through second junction members 152. In proximity? of a second extremity? 132 of the second lateral structural element 13? a second support element 162 of the rib 10 is provided which incorporates and defines another foot of the rib.

A second end? 132 of the second lateral element 13? operationally connected to a first end? 141 of the bottom structural element 14. The connection between the second end? 132 of the second lateral structural element 13 and the first end? 141 of the bottom structural element 14? achieved through third junction bodies 153.

The bottom structural element 14 has a second end? 142 intended to be connected on site, in the definitive configuration of the rib 10 illustrated in figure 2, to the second end? 112 of the first lateral structural element 11. The connection between the second end? 142 of the bottom structural element 14 and the second end? 112 of the first lateral structural element 11? made through fourth joints 154.

Advantageously, the first 151, second 152 and/or third 153 joint members are articulated, oscillating or rotatable joint members. Preferably, the first 151, second 152 and/or third 153 joint members are hinges. The structural elements coupled via these junction members can therefore move from a first installation position of the rib 10, in which the structural elements are substantially folded over each other, as visible in figure 1, to a second definitive position of the rib 10, as visible in figure 2, in which the structural elements are arranged to form at least a substantially continuous portion of the rib. Preferably, but not limitedly, in the installation configuration of the curtain rod 10 the second end? 142 of the bottom structural element 14? made in such a way as to be slidably coupled to the body of the first lateral structural element 11. In this way, continuity is obtained. assembled between the structural elements of the rib 10 also in the folded installation form illustrated in figure 1. It turns out like this? It is particularly easy and advantageous to transport inside the excavation S the rib 10 folded on itself in the installation configuration, in which the structural elements 11, 12, 13, 14 are joined to each other in continuity. without any of their ends? is freely floating.

Overall, in the definitive form, or almost? of the rib illustrated in figure 2, the structural elements 11, 12, 13, 14 form a closed figure seen from the front. In this configuration, the first 161 and the second 162 support elements, i.e. the two feet, protrude externally and laterally from the closed figure of the rib 10. The support elements 161, 162 are preferably extendable and can be extended by an amount adjustable to rest on the ground, in particular on the respective flat lateral areas M of the excavation S. As visible in figure 2, the support element 161, on the left in the figure, is elongated and rests on the ground, while the support element 162, on the right in the figure, ? shown in a retracted position, before being extended to rest on the ground in the final configuration of the rib 10.

In figure 3? illustrated is an example of the realization of one of the support elements 161 or 162, i.e. one of the feet of the rib 10. The support element 161 or 162 includes a fixed structure 16 and a mobile structure 17 mounted in an extensible manner with respect to the fixed structure 16. The fixed structure 16? fixed to a corresponding lateral structural element 11 or 13, preferably in proximity to of its second extremity? 112 or 132, respectively. The fixed structure 16 can? be fixed to the lateral structural element 11 or 13 by any known system, for example by welding or with bolts or rivets or other connecting members of the kind. The fixed structure 16? made preferably, although not necessarily, with the same metallic material as the lateral structural element 11 or 13, such as for example construction steel (Fe 430 or other). Preferably, the fixed structure 16? made with a profile with an open cross section, for example H or C or double T, for example a European standardized profile such as HEA, HEB, HEM, IPE, etc. Preferably the fixed structure 16? made with a profile having the same section and the same dimensions as the profile of the lateral structural element 11 or 13, as clearly visible in the example of figure 3.

The mobile structure 17 can? be preferably made with a tubular body, for example with a square or rectangular section, and in any case configured and sized in such a way as to slide linearly with respect to the fixed body 16, preferably telescopically, without the possibility of of rotation. At the extremity lower part of the mobile structure 17, intended to rest on the ground,? a support plate 18 is fixed. The support plate 18 has dimensions larger than the section of the mobile structure 17, to form a support base sufficiently extended to distribute the weight over a relatively large surface of the lateral flat area M of the excavation S. The plate of support 18 preferably extends for the most part towards the inside of the rib 10, i.e. respectively towards the end? 112 or 132 of the structural element 11 or 13, where it forms a wing 19. Some reinforcements 20, also called gussets, preferably made of a flat sheet metal, are fixed, preferably welded, between the support plate 18 and the mobile structure 17, to reinforce the connection between these two elements and stiffen the support plate 18.

From the installation configuration, shown in figure 1 or, with reference to the right foot, in figure 2, the mobile structure 17 can? be lengthened with respect to the fixed structure 16 up to the definitive configuration illustrated with reference to the left foot in figure 2. The lengthening of the mobile structure 17 can happen in direct motion, while the possibility is prevented? of retrograde motion, i.e. shortening of the foot. For this purpose it can a ratchet 21 can advantageously be provided, which for example includes a toothed rod 22 with saw teeth. The end points to the teeth of the toothed rod 22. 23a of a flexible metal tongue 23, acting as a pawl. The toothed rod 22 can be fixed, for example welded or screwed, on one side of the mobile structure 16. The metal tab 23 can? the other end? 23b fixed to the upper portion of the mobile structure 17.

In figures 4 and 5? another example of the realization of one of the support elements of the rib 10 is illustrated. In this case the support element 161? or 162? comprises a structure 25 pivoted and oscillating according to a horizontal rotation axis on the lateral structural element 11 or 13 via a pin 26. The structure 25 is made preferably, although not necessarily, with the same metallic material as the lateral structural element 11 or 13, such as for example construction steel (Fe 430 or other). The structure 25 includes two cheeks 25a, 25b connected by crosspieces 27. Each cheek 25a, 25b includes two branches 28a, 28b which extend from the pivoting area of the pin 26 up to a circular arc element 29. A toothed toothing 30 of saw on the edge more? outside of one or both of the circular arc elements 29 contributes to the creation of a ratchet 31. The extremity points to the teeth 30. of a flexible metal tab 32, acting as a pawl, fixed to the structural element 11 or 13.

From the installation configuration, drawn with a dotted line in figure 4, the structure 25 can? be rotated around the horizontal axis of the pin 26, until the final configuration illustrated in solid lines in figure 4. Thanks to the ratchet 31, the rotation of the structure 25 is possible. permitted in direct motion, i.e. clockwise in figure 4, while the possibility is prevented? of retrograde motion, counterclockwise in figure 4. Advantageously, the junction members 151, 152, 153 for connecting the structural elements 11, 12, 13, 14 can comprise at least one engagement element associated with at least one elastic member. The elastic members of the joint members 151, 152, 153 allow a snap joint to be made in the final position of the rib. The snap connection determines the precise relative position of each structural element relative to adjacent structural elements, so? to create a rib having a substantially pre-established geometric and dimensional configuration as per the project, as well as? stable and resistant to the thrusts exerted on it by the walls of the excavation S.

In figures 6 and 7? illustrated is an example of the junction member 151, similarly applicable also to one of the other junction members 152 and/or 153 which connect the structural elements 11, 12, 13, 14 to each other in an articulated manner as previously described.

The joining member 151 illustrated in figures 6 and 7 includes two portions 151a, 151b hinged to each other, for example by means of a pin 40, fixed respectively to one and the other of the ends? 111, 121 of the structural elements 11, 12 to be connected. The first portion 151a includes two cheeks 42a, 42b joined by a bottom wall 43 with two perforated appendages 44 within which? inserted the pin 40. The first portion 151a has an overall U-shaped or rectangular box-shaped section, as visible in figure 7. In the first portion 151a you can the second portion 151b be housed. The second portion 151b can? be made by means of a tubular appendage 48 protruding from the end 121 of the structural element 12. The tubular appendage 48 preferably has a square or quadrangular section, with two side walls 49a, 49b which, in the definitive configuration illustrated in figures 6 and 7, are placed alongside the internal surface of the cheeks 42a, 42b of the first portion 151a.

Two respective holes 50 are made on the cheeks 42a, 42b of the first portion 151a which, in the definitive configuration illustrated in figures 6 and 7, are aligned with two corresponding holes 51 made on the side walls 49a, 49b of the tubular appendage 48. These holes 50 , 51 are crossed by two pegs 52 housed inside the tubular appendage 48 and pressed outwards by a spring 54 contained in a guide tube 55. Initially, when the rib 10 is in the installation configuration of figure 1, the pegs 52 can be retained inside the second portion 151b for example by means of two thin metal plates (not shown), welded externally to the two side walls 49a, 49b so as to cover the holes 51. By forcing the second portion 151b inside the first portion 151a, the metal plates that hold the pins 52 are torn from the cheeks 42a, 42b in such a way that the pins 52, pushed outwards by the spring 54, first rest on the internal surface of the cheeks 42a, 42b and subsequently, continuing the relative rotation of the two portions 151a, 151b, engage the holes 50 on the cheeks 42a, 42b, definitively locking, by snapping and in a substantially irreversible manner, the structural elements 11, 12 in the configuration definitive of the rib 10.

The junction members 154 for connecting the bottom structural element 14 to the first lateral structural element 11 can also include at least one engagement element associated with at least one elastic member. This elastic member allows a snap joint to be created in the final position of the rib. The snap connection determines the precise relative position of the bottom structural element 14 with respect to the adjacent side structural element, thus to create a rib having a substantially pre-established geometric and dimensional configuration as per the project, as well as? stable and resistant to the thrusts exerted on it by the walls of the excavation S.

As visible in figure 8, an example of junction member 154 for connecting the bottom structural element 14 to the first lateral structural element 11 includes two portions 154a, 154b fixed respectively to one and the other of the ends 112, 142 of the structural elements 11, 14 to be connected. The first portion 154a includes two opposing cheeks 62, joined by a bottom wall 63. Two respective holes 64 are provided on the cheeks 62, preferably coaxially aligned. Overall, the first portion 154a therefore has a U-shaped cross section. As visible in figure 9, which shows the joining member 154 in the coupled condition, two recesses 61 protrude inwards from the cheeks 62.

In the first portion 154a can? the second portion 154b be housed. As also visible in figure 10, which shows only the second portion 154b seen from the opposite side compared to the view in figure 8, the second portion 154b can include two opposing cheeks 66, protruding from the extremity? 142 of the structural element 14. The cheeks 66 are joined by an end wall 65 fixed at the end 142 of the bottom structural element 14. Two respective holes 67 are provided on the cheeks 66, preferably coaxially aligned. Between the two cheeks 66? a coupling body 68 is mounted. The coupling body 68 includes two cheeks 69. The two cheeks 69 are joined by an upper wall 72. On the side opposite to the upper wall 72, the two cheeks have an arched edge 69a, as clearly visible in the figures 11 and 12. On the cheeks 69 there are two respective holes 70, preferably coaxially aligned, each of which is ? coaxially aligned with the hole 67 obtained on a respective cheek 66 facing the cheek 69. In an area around the holes 70, the cheeks 69 include a thicker portion 71 which defines a step 73 against which, in the coupled position illustrated in figure 9 , the recesses 61 of the first portion 154a of the joining member 154 abut, so as to prevent it from moving away and detaching from the second portion 154b.

The holes 70 are crossed by two pegs 77 housed inside the coupling body 68 and pressed outwards by a spring 74 which can be contained preferably but not limitedly in a guide tube 75, in a substantially similar manner to what was seen previously with reference to the connecting member 151. Initially, when the rib 10 is in the installation configuration of figure 1, the pegs 77 can be held inside the coupling body 68 for example by means of two thin metal plates 76, welded externally to the two cheek walls 69 so as to cover the holes 70. By forcing the second portion 154b inside the first portion 154a, the metal plates 76 that hold the pegs 77 are torn from the cheeks 69 in such a way that the pegs 77, pushed outwards by the spring 74, first come to rest on the internal surface of the cheeks 62 of the first portion 154a and subsequently, continuing the insertion of the second portion 154b into the first portion 154a, engage the holes 64 on the cheeks 62, definitively locking, by snapping and in a substantially irreversible manner, the structural elements 11, 14 in the definitive configuration of the curtain 10. The achievement of this definitive position, illustrated in figures 9 and 11, can? be checked by visually checking through the holes 67 on the cheeks 66 of the second portion 154b that the pegs 77 are in the correct position of engagement in the holes 64. on the cheeks 62.

As previously described, the bottom structural element 14 can be slidably connected to the lateral structural element 11 before being brought into the blocked configuration of figure 9. Figures 11 and 12 illustrate a lateral view of the two positions assumed by these two structural elements shortly before and shortly after reaching the definitive configuration, blocked by the joint member 154. In the example of the figures, the lateral structural element 11 is made with an H-shaped beam, which includes two flat portions 80, 81 connected by a central isthmus 82. Two pins 84 protruding towards the inside can optionally be fixed on the cheeks 66 of the second portion 154b, which remain hooked below the portion flat portion 81 of the beam which constitutes the lateral structural element 11. The curved edge 69a of the cheeks 69 instead slides on the external surface of the flat portion 81. In this way, the flat portion 81 acts as a sort of linear guide for the end 142 of the bottom structural element 14, and in particular for the second portion 154b of the junction member 154. The second portion 154b can then slide on the flat portion 81 while the rib 10 passes from the installation configuration to the definitive configuration illustrated in figure 12. The possible presence of the pins 84 helps to prevent the second portion 154b from sliding on the flat portion 81 without the risk of moving away from it.

In figures 13 and 14? illustrated an example of a 90 elastic joint that can? be inserted between two sections of a structural element 11, 12, 13 and/or 14 of the rib 10. In particular, the adoption of one or more? elastic joints 90 allows you to absorb, by reacting elastically, the thrusts which over time may be exerted by the walls of the excavation S on the rib 10. The elastic joint 90 can be introduced on one or more? of the structural elements 11, 12, 13, 14, even if more? preferably it is introduced mainly on the central structural element 12 and/or on both lateral structural elements 11, 13. On one or more? of the structural elements can be introduced even more? elastic joints 90.

Taking the central structural element 12 as a non-limiting example (as said previously, similar considerations can be carried out with reference to the other structural elements), between its two portions 12a, 12b? inserted an elastic joint 90, which includes two portions 90a, 90b. The portions 90a, 90b are coupled together in a sliding manner, preferably in a telescopic manner, and are preferably locked in mutual rotation. The two portions 90a, 90b are preferably made by means of two cylindrical sleeves inserted into each other. To block the portions 90a, 90b in mutual rotation can? a pin 91, or a pair of preferably diametrically opposed pins 91, which engages in a slot 92 or in a corresponding pair of slots 92, can be provided. The pin 91 or the pins 91 can be mounted on the sleeve external 90b, while the slot 92 or the slots 92 are obtained on the sleeve internal 90a, as visible in figure 13. Inside the sleeves 90a, 90b? a first spring 93 is inserted and rests against respective end walls. 94a, 94b of the sleeves 90a, 90b. A second spring 95, more? short of the first spring 93, ? mounted inside a tubular housing 96 fixed to one of the two end walls? 94a, 94b of the sleeves 90a, 90b. In the extended condition of the elastic joint 90, which normally corresponds to the definitive configuration of the rib 10 just mounted in the excavation S, the first spring 95 rests against respective end walls. 94a, 94b of the sleeves 90a, 90b and is compressed as soon as the two portions 12a, 12b of the central structural element 12 come together following a compression thrust exerted by the walls of the excavation S on the rib 10. As the compression increases , the end walls? 94a, 94b move closer, compressing the spring 95 which exerts an increasingly greater elastic force. If the compression increases further, the two walls 94a, 94b become so close that the second spring 96 also comes into operation, whose elastic thrust is added to that of the first spring 95, so to withstand a greater compression thrust from the walls of the excavation S on rib 10.

In figure 15 ? illustrated in perspective a junction member 180 which can? be used as a variant of articulated connection between two structural elements of the rib, as an alternative to the joining member illustrated in figure 6. The joining member 180 can? therefore serve to connect the structural elements 11, 12, 13 and/or 14 of the rib 10. The figure takes as an example the articulated connection between the lateral structural element 11 and the central structural element 12. At the first end? 111 of the lateral structural element 11? a transversal plate 181 is fixed, from which a pair of external cheeks 182 parallel to each other protrudes orthogonally. Similarly, at the first end? 121 of the central structural element 12? a transversal plate 183 is fixed, from which a pair of internal cheeks 184 parallel to each other protrudes orthogonally. The internal cheeks 184 are spaced from each other in such a way as to fit between the external cheeks 182. In this way the external surface of each internal cheek 184 is placed close to the internal surface of a corresponding external cheek 182. A pin 185 passes transversally through both the cheeks external 182 and the internal cheeks 184 for the articulated junction of the lateral 11 and central 12 structural elements. The pin 185 can? have an enlarged head on one side and on the other side it can? be held in position by known means, such as split pins, snap rings, and other generally known systems.

On one of the two structural elements, for example the central structural element 12 in the non-limiting example of figure 15, there is an elastic blocking member of the junction member 180 is fixed which blocks the structural elements in the definitive position of the rib 10. In the example of figure 15, the elastic element is formed by a metal plate 186 which is fixed on one side, for example by welding, to one of the two structural elements, in the example the central structural element 12.

As illustrated in figure 16, in the non-blocked installation configuration of the junction member 180, the plate 186 is forced into bending in such a way that the extremity? free presses on the external cheeks 182 of the joint member 180. In particular, two end teeth 187 do they press against the edges 182? of the external cheeks 182 thanks to the elasticity? of the plate 186 which tends to assume a flat configuration. On the edges 182? of the external cheeks 182 two respective recesses 188 are obtained in which, following a reciprocal rotation of the lateral 11 and central 12 structural elements, the teeth 187 snap into engagement, blocking the joint member 180 in the definitive configuration of the rib 10 , illustrated in figure 17.

In figure 18? illustrated in perspective a junction member 190 which can? be used as a variant of articulated connection between two structural elements of the rib, as an alternative to the joining member illustrated in figure 6 or in figure 15. The joining member 190 can therefore serve to connect the structural elements 11, 12, 13 and/or 14 of the rib 10. The joining member 190 includes a first transverse plate 191 which is fixed to one end of a structural element of the rib 10. Two external cheeks 192 parallel to each other protrude orthogonally from the first plate 191. The joining member 190 includes a second transverse plate 193 which is fixed to one end of another structural element of the rib 10. Two internal cheeks 194 parallel to each other protrude orthogonally from the second plate 193. The internal cheeks 194 are spaced apart in such a way as to fit between the two external cheeks 192. In this way the external surface of each external cheek 194 is placed close to the internal surface of a corresponding external cheek 192. A pin 195 crosses transversally both the external cheeks 192 and the internal cheeks 194 for the articulated junction of the two structural elements to which the first plate 191 and the second plate 193 are fixed. The pin 195 can? have an enlarged head on one side and on the other side it can? be held in position by known means, such as split pins, snap rings, and other generally known systems.

Through holes 196 are provided on the external cheeks 192 and on the internal cheeks 194, preferably but not limited to four on each cheek. The holes 196 on each external cheek 192 are aligned axially with the holes on each adjacent internal cheek 192 only in the definitive configuration of the structural elements coupled by the joint member 190. This position corresponds to that illustrated in figure 18. In this position, the holes 196 aligned on each cheek 192. 194 are engaged by a corresponding pin 197 pressed outwards by a spring 198 inserted in a tube 199 mounted between the two internal cheeks 194, in a similar way to what was seen previously with reference to the block snap mounted at the end? of the bottom structural element and illustrated in figure 7. To prevent the pegs 197 from blocking the joint member 190 in an angular position different from the definitive one illustrated in figure 18, the four holes 196 on each cheek are each arranged at a different radial distance with respect to the mutual rotation center of the external cheeks 192 and internal 194 defined by the pin 195. In this way, in any mutual angular position of the internal and external cheeks other than the definitive one, the pins 197 which house in the holes 196 on the internal cheeks 194 collide against the internal surface of the internal cheeks 192. Only when the joining member 190 reaches the definitive configuration, the holes 196 on the internal and external cheeks align coaxially and the pins 197, under the pressure of the springs 198, can engage the corresponding holes 196 on the external cheeks 192, blocking the mutual rotation of the structural elements fixed to the junction member 190.

The ribs 10 are connected in operation to each other by means of connecting members, also known in the sector as "chains". In figure 19? illustrated is an example of a connecting member 200 between a rib 10 and an adjacent rib 10?. The connecting member 200 includes a bar 201 fixed at one end thereof. 202 on the rib 10. On the rib 10? for example, a housing 203 is foreseen in which? inserted the end? 202 of the bar 201, blocked by a pin, pin or bolt 204. The bar 201 protrudes from the rib 10 in a substantially transversal direction and ends on the other side with a bent section 205, intended to fit into an eye 206 fixed to the other rib 10?. The bent section 205 ? provided with an elastic locking member 207 which snaps it into place in the eye 206, preventing it from escaping in retrograde motion. The elastic blocking member 207 is formed for example by a flexible metal tab fixed to the end? of the bent portion 205, in the shape of an arrow, as clearly illustrated in figure 19.

In figure 20? another example of connecting member 400 between a rib 10 and an adjacent rib 10? is illustrated. The connecting member 400 includes a bar 401, for example but not limited to a quadrangular tubular bar like the one illustrated in the figure. The 401 bar? fixed swinging at one end? 402 to the rib 10. For this purpose, for example, two cheeks 403 can be provided on the rib 10, between which ? inserted the end? 402 of the bar 401, crossed by a pin, pin or bolt 404. The bar 401 protrudes from the rib 10 in a substantially transversal direction and ends on the other side with a section of hook 405, intended to be inserted into a slot 406 fixed to the ?another hundred 10?. The hook section 405 ? equipped with an end tooth? 407 which snaps onto an oscillating plate 408 forced by a spring 409 which, for clarity of illustration, is shown in the figure with reference to the rib 10, provided with a similar slot for attachment to the previous rib. A plate 410 pushes the bar 401 in the opposite direction to the insertion of the end tooth. 407 in the slot 406. of exit from the slot 406, movement prevented.

To hook the rib 10 to the rib 10?, push the hook section 405 of the bar 401 into the slot 406, counteracting the thrust exerted by the plate 410 on the bar 401. The end tooth? 407 lifts the oscillating plate 408 counteracting the thrust of the spring 409 until, once past the end tooth, 407, the oscillating plate 408 snaps under the end tooth? 407 by blocking the hook section 405 in the slot 406. The thrust of the plate 410 on the bar 401 ensures the tightness of the connection between the rib 10 and the rib 10?.

In figure 21? illustrated is a variant of the rib 210, which differs from the rib described previously in that the bottom structural element 214 is? initially separated from the lateral structural elements 211, 213, and is fixed to them only after they have assumed a substantially definitive configuration. The lateral structural elements 211, 213 are articulated to the central structural element 212 in a manner similar to that previously described, through the junction members 151, 152. The bottom structural element 214 is fixed via end connectors? 220 which engage within seats 221 obtained on the lateral structural elements 211, 213, in proximity to of the support elements 161, 162.

In figure 22 ? shown in more detail is an example of connecting an?end? 214? of the bottom structural element 214, provided with the end connector? 220, to a lateral structural element, for example the lateral structural element 211. The end? of the lateral structural element 211 ? configured to define the seat 221 of the end connector? 220. In particular, the seat 221 includes two lateral cheeks 222. Two respective through holes 223 are obtained on the lateral cheeks 222, aligned axially with respect to a transversal axis. At the extremity of the lateral cheeks 222 two respective recessed lips 224 are provided which define a notch 225.

The end connector? 220, also illustrated in Figure 23, includes a neck 228 protruding from the end 214? of the bottom structural element 214. Around the neck 228 ? a spherical joint 229 is fixed. The ball 230 of the spherical joint carries two opposing pins 231, pushed outwards by a spring (not visible) housed inside the sphere 230. The spherical joint 229 allows rotations and torsions to be compensated of the structural element 211, and in particular of the seat 221 with respect to the bottom structural element 214. In the blocked configuration of the end connector? 220 in seat 221, neck 228? inserted into the notch 225 and the pegs 231 snap into the through holes 223 on the side cheeks 222. The structure of the end connector? 220 and headquarters 221? repeated substantially mirrorwise at the other end? of the structural element 214, for connection to the other lateral structural element 213.

In figure 24 ? shown in more detail is another example of connecting an?end? 214? of the bottom structural element 214, provided with an end connector? 240, to a lateral structural element, for example the lateral structural element 211. The end? of the lateral structural element 211 ? configured to define a seat 241 of the end connector? 240. The seat 241 includes two lateral cheeks 242. Two respective through holes 243 are provided on the lateral cheeks 242, aligned axially with respect to a transversal axis. The side cheeks 242 have an end edge 244 is preferably configured so as to be substantially vertical with respect to the definitive position of the lateral structural element 211. The end connector? 240, includes a plate 245 which defines two surfaces 246 oriented substantially parallel to the end edges 244 of the lateral cheeks 242. Two cheeks 247 protrude orthogonally from the plate 245 and are connected by a wall 248. On the side opposite to the wall 248, the cheeks have an arched edge 247a which facilitates sliding on the upper portion of the lateral structural element 211, similarly to as seen previously in relation to the connecting member illustrated in figures 11 and 12. Two holes 249 are provided on the cheeks 247, aligned axially along a transversal axis. Two corresponding pegs 250 are inserted into the holes 249 and pushed outwards by a spring 251 arranged inside the cheeks 247. Before the end connector? 240 engages the seat 241, the pegs 250 are held by sacrificial plates or bars 252 which are removed or torn when the cheeks 247 penetrate inside the cheeks 242. After this introduction, the pegs 250 are free to engage the photos 243 and block what? the link. Advantageously, the sliding of the edge 244 of the cheeks 242 on the surfaces 246, preferably in a vertical direction, considerably facilitates the connection and makes the connection easy, economical and simple to make and install.

Naturally, the connections illustrated in figures 22, 23 and 24 can be applied indifferently to the case in which the bottom structural element is articulated on one side to a lateral structural element, as illustrated in figure 1, or in the case in which it is separated, as in the case of figure 21. Will it be discussed? in one case to make the connection on only one end? of the underlying structural element, or on both.

In figure 25 ? illustrated is a variant of rib 310, which differs from the ribs described previously in that the bottom structural element 14 is? divided into two portions 14a, 14b. In the example illustrated in figure 25, the two portions 14a, 14b of the bottom structural element 14 are each connected in an articulated manner to a respective second end. 112, 132 of a lateral structural element 11, 13. In the example illustrated in figure 25 there are therefore four junction members 151, 152, 153, 153? articulated, while the two portions 14a, 14b of the bottom structural element 14 can be connected by means of a junction member 353 substantially the same as that described and illustrated previously with reference to figures 8? 12. Alternatively, the two portions 14a, 14b can be connected to each other by means of a junction member substantially the same as that described and illustrated with reference to figures 21 and 22. It is not naturally it is excluded that the joining of the two portions 14a, 14b can take place in any other way, for example with a traditional bolted connection system. In figure 25 ? the rib 310 is illustrated both in the installation configuration, with the structural elements folded, and in the definitive open configuration, supporting the wall of the excavation S.

The ribs described previously, whether of the type illustrated in figure 1, or in figure 21 or in figure 25, are transported to the excavation site S in the configuration in which the structural elements are folded, to assume a compact configuration whose extension on the plane which contains the structural elements? lower than the extension of the section of the excavation S. In the event that the arch has no underlying structural element, as in the example of figure 21, this can be transported to the excavation site S together with the rib 210, or supplied after the definitive laying and installation of the rib 210. In the case of the rib 10 of figure 1, transport and installation take place with the second end portion 142 of the bottom structural element 14 which is far from the second portion of the extremity? 112 of the lateral structural element 11.

The support elements of the rib 161, 162 are preferably raised. Transport therefore takes place easily and the elements that make up the curtainsider are already there? prepared for correct positioning in the final configuration.

When the hundred? in the expected position inside the excavation S, the central structural element is lifted so that the other structural elements rotate at the articulated joints to move into an open configuration, as illustrated for example in figure 2. With the structural element central positioned in correspondence with the upper wall of the excavation, the lateral structural elements adjacent to it are placed next to the side wall of the excavation. The bottom structural element, whether in one piece as in the example in figure 1 or in two portions as in the example in figure 25, is lowered until it is positioned at the bottom of the excavation.

The lowering of the underlying structural element 14 is facilitated in the case in which it is slidingly constrained to the lateral structural element as in the example of figure 1. In this position it is Is it possible to connect its second end? of the bottom structural element 14 at the second end? of the lateral structural element 11, so as to establish continuity? overall structural structure of the rib. The lowering of the bottom structural element 14 can be facilitated by pushing the lateral structural elements of the rib away from each other. Conversely, if necessary, pushing the bottom structural element 14 downwards? It is possible to exert a widening thrust on the lateral structural elements. Similarly, also the connection of the two portions 14a, 14b of the bottom structural element 14 of the example in figure 25, or the insertion of the bottom element 214 between the ends? lower of the two lateral structural elements in the example of figure 21 determines a widening thrust on the latter.

At the end of the relative rotation, the structural elements are fixed in the installation position using the above-mentioned joints. The creation of the snap joints ensures that the structural elements remain firmly in the desired design position once the installation is completed, without the risk of them closing on each other. The support elements are arranged laterally and below the side walls of the excavation, and are extended or rotated until they touch the ground. The installation of the curtain therefore occurs quickly and substantially automatically.

Each rib is then connected to an adjacent rib by means of connecting members called "chains", two examples of which have been described with reference to figures 19 and 20. The connecting members are made in such a way as to preferably allow an automatic connection of a one hundred at a time.

Preferably, the ribs used for the support and consolidation of an excavation have elastic joints, for example of the type described previously and illustrated in figures 13 and 14, which can be inserted between two sections of the structural elements of the rib. The adoption of one or more? elastic joints allow the thrusts that may be exerted by the walls of the excavation on the rib to be absorbed, reacting elastically, over time.

Variations with respect to what was previously described are naturally possible, without this? modify the claimed inventive concept. For example, in some rib configurations, depending on the geological conformation of the excavation, the lateral support members, i.e. the feet of the rib, may not be necessary, or it may be necessary to use only one of them instead of both.

The main inventive concept of the invention is not? depending on the type of profile used. Although open cross-section profiles were previously mentioned as preferable, they are not? excluding the use of the invention with tubular profiles with which to create all or part of the overall profile of the rib and/or one or more? of its structural elements. In general terms, ? However, it is possible to use different profiles for different portions of the rib, the possibility not being excluded. to use different profiles also for parts of structural elements, with open and/or closed/tubular profiles, separated from each other for example by the elastic joints described previously.

Naturally, without prejudice to the principle of the invention, the forms of implementation and the details of construction may vary widely with respect to what has been described and illustrated, without thereby departing from the scope of the present invention.

Claims (10)

1. Curtain for the support and consolidation of an excavation, including more? structural elements (11, 12, 13, 14) mobile connected to each other so that the rib can go from a pre-assembled configuration at least partially folded before installation, to a definitive installation configuration in which the structural elements are blocked with continuity? structural with respect to each other in a reciprocal position which overall defines an arched rib. 2. Curtain according to claim 1, in which the structural elements are continuously blocked? structurally with respect to each other in a reciprocal position which overall defines a rib with a closed geometric profile, including an arched rib closed at the bottom by a structural element acting as a strut or inverted arch. 3. Curtain according to claim 1 or 2, in which the structural elements are mounted articulated to each other by means of hinges. 4. Rib according to any of the previous claims, wherein a structural element with the function of a strut or inverted arch has an extremity mounted sliding on another, different structural element. 5. Curtain according to any one of claims 1 to 3, wherein a structural element acting as a strut or inverted arch has two end connectors? for connection in seats made on two opposing lateral structural elements of the rib. 6. Curb according to any of the previous claims, in which a structural element with the function of a strut or inverted arch comprises two portions articulated respectively to two lateral structural elements, a junction member being provided to join the two portions in the definitive installation configuration of the hundred. 7. Curtain according to any of the previous claims, comprising at least three structural elements, or at least four structural elements, or at least five structural elements, preferably made entirely or partially in at least two sections between which elastic joints are inserted. 8. Method for installing a rib inside an excavation according to any of the previous claims, comprising the steps of: - prepare more? structural elements (11, 12, 13, 14) of a rib (10); - movably connect said structural elements to each other to obtain a pre-assembled rib - fold the rib at least partially before its installation, - transport the rib at least partially folded inside the excavation, - install the curtainsider in a definitive installation configuration by blocking the structural elements with continuity? structural with respect to each other in a reciprocal position which overall defines an arched rib. 9. Method according to the previous claim, comprising the final step of blocking the structural elements with continuity? structurally with respect to each other in a reciprocal position which overall defines a rib with a closed geometric profile. 10. The method according to claim 8 or claim 9, wherein the structural elements are irreversibly locked relative to each other.