PT95523A - PREFABRICATED METALLIC METALLIC STRUCTURE FOR USE IN A THREE-DIMENSIONAL METALLIC STRUCTURE AND CONSTRUCTION PROCESS OF A THREE-DIMENSIONAL STRUCTURAMETALIC - Google Patents

Description

WARD BUILDING SYSTEMS LIMITED " THREE-DIMENSIONAL METALLIC STRUCTURE, PREFABRICATED ASSEMBLY FOR USING THESE THREE-DIMENSIONAL METALLIC STRUCTURE AND CONSTRUCTION PROCESS OF A THREE-DIMENSIONAL METALLIC STRUCTURE " The present invention relates to three-dimensional structures.

Three-dimensional structures are known and widely used in building construction, in circumstances where it is intended to cover a substantial area and which must be free of supporting pillars.

An object of the present invention is to provide a new and improved three-dimensional structure.

According to a first aspect of the present invention, there is provided a three-dimensional structure having a first rope structure, a second rope structure and a diagonal structure consisting of diagonal members connecting the rope structures, the rope comprising one of the rope structures being first and second rope elements connected together in side-by-side relationship and said rope elements being connected to ropes of the other rope structure by said diagonal structure.

According to a further aspect of the present invention there is provided a prefabricated assembly for use in a three-dimensional structure, the assembly comprising two rope elements that are spaced from one another and connected to each other by diagonals extending obliquely to each other, the rope elements parallel to one another and providing fastening means by which the prefabricated assembly can be secured to another prefabricated assembly.

According to a third aspect of the present invention there is provided a method of constructing a three-dimensional structure comprising a number of interconnected prefabricated elements, each set comprising two diagonally interconnected rope elements comprising the steps of: juxtaposing two assemblies such that the rope element of one of the assemblies is side-by-side with a rope element of the other of the assemblies, and to connect the assemblies together.

A three-dimensional structure according to the present invention comprises a reduced number of different elements and is relatively inexpensive, simple and quick-fit to provide the three-dimensional structure.

Specific embodiments of the present invention will now be described, by way of example only and with reference to the accompanying drawings, in which: 1 is a perspective view of parts of two prefabricated assemblies suitable for the construction of a three-dimensional structure according to the present invention; FIG. Figure 2 is a plan view of part of a three-dimensional structure constructed from the prefabricated assemblies shown in Fig. 1; FIG. 3, a cut made by (A-A) in Fig. 2; FIG. 4 is an enlarged view of parts of the prefabricated assemblies of Fig. 1, just before mutual bonding; FIG. 5, a cut made by (B-B) of Fig. 4; FIG. 5a, a view similar to Fig. 5, but showing the sets when connected together; FIG. 6 is a schematic cross-section of part of an alternative embodiment of a three-dimensional structure according to the present invention; FIG. 7, a part of yet another embodiment of a three-dimensional structure according to the present invention; FIG. 8 is a section through part of another embodiment of a three-dimensional structure according to the present invention; FIG. 9, an enlarged view of part of the construction shown in Fig. 8 and referenced with letter (P); FIG. 10 is a part view of the construction shown in Fig. 8, seen in the direction of the arrow R of FIG. 9; FIG. 11 is a schematic cross-section of yet another embodiment of the three-dimensional structure according to the present invention; FIG. 12 is a detail of one end of a diagonal as shown in FIG. 8; and Fig. 13 shows a detail of the connection between the end of the diagonal shown in Fig. 12 and a rope element.

With reference to Figures 1 to 5 of the drawings, a three-dimensional structure comprises a number of rope elements (1) of a rope structure which, in use, is superior to the surface on which the three-dimensional structure extends, and a a number of rope elements (2) of a rope structure which, in use, is lower than the upper rope structure relative to the surface.

A number of diagonals (3) hold apart and join the rope structures together.

Pairs of rope elements (1) in the upper rope structure are secured together in side-by-side relationship to form ropes (40). Similarly, pairs of rope elements (2) in the lower rope structure are similarly attached to form strings (41).

The strings 40 in the upper strut structure are spaced apart from each other the same distance as between adjacent strings 41 in the lower strut structure. In addition, the strings 40 and 41 in both straddle structures extend parallel to each other.

Each rope element 1 and 2 in each of the rope structures is connected to an adjacent rope only in the other rope structure by diagonals 3. In addition, the strings 40 in the upper strut structure are laterally offset from the strings 41 in the lower strut structure so as to be disposed midway therebetween. The three-dimensional structure is constituted by a number of prefabricated sub-units which are transported to the place of use in a constructive manner. Each prefabricated assembly comprises two rope elements 1 and 2, spaced apart and connected to each other by the diagonals 3, as shown in Fig. 1. Such a prefabricated assembly may be readily juxtaposed with another prefabricated assembly in a manner such that the assemblies may be secured together to provide a composite of two such assemblies, which may then be juxtaposed and secured with one or more other sets.

By providing prefabricated assemblies of this type, it is indeed possible to construct very quickly a tridimensional structure.

Each of the rope elements 1 and 2 in the embodiment of the three-dimensional structure shown in FIGS. 1 to 5 comprises a U-shaped member with first and second parallel flaps (5, 6), spaced apart and connected by a web (4).

The diagonals (3) comprise an element having a tubular rectilinear medial portion (7) and flattened end portions (8) which extend substantially parallel and in opposite directions to each other away from the medial portion. This is best seen in Fig. 4. Each of the end portions 8 of the diagonals 3 has an aperture 9 extending therethrough and into which a stem 20 of a screw 21 can be received.

Each of the rope elements 1 and 2 provides, in longitudinally spaced positions in the webs 4 thereof, apertures 10 extending through the web 4 and which are capable of receiving the rod 20 ) of a screw (21).

The apertures 10 are provided to the pairs in the web 4, the apertures 10 of each pair being at a small distance from each other and being provided at equal distances longitudinally in the web. The arrangement of the apertures 10 in the webs 4 of a rope element 1 relative to the positions of the apertures 10 in the webs 4 of the rope elements 2 is such that in the three-dimensional structure constructed the apertures in the (4) of the rope elements (1) are in positions intermediate the positions of the apertures (10) in the web elements (4) of the rope elements (2). Accordingly, the diagonals (3) extend obliquely between the elements between the adjacent rope elements in the upper and lower rope structures.

The pairs of rope elements (1) comprising a rope (40) in the upper rope structure are secured to each other by means of a screw (21) passing through holes (10) aligned in the webs (4) of the elements of rope (1) and in an analogous manner pairs of rope elements (2) in the other rope structure (41) are also secured together by screws.

The diagonals 3 are also connected to the rope elements 1 and 2 by means of screws 21 and by means of reinforcing plates 22 which are interposed between the screw heads 23 and each end part (8) of the diagonals (3), so that the end part (8) of each diagonal (3) is interposed between a rope element (1) and (2) and the reinforcement plate (22). As shown in Fig. 5, the reinforcing plates 22 are formed of plates, each of which provides two holes 24 through which the screw rods 20 can be received. Accordingly, each of the reinforcing plates covers two openings 10 in the web 4 of a rope element 1 and 2 and serves to cover the end portions of two diagonals 3 in the place where they are connected to the rope element, in such a way that the end portions (8) of the diagonals (3) do not overlap each other.

FIG. 4 and 5 show a detail of two prefabricated assemblies just before securing the assemblies together. As can be seen from FIGS. 4 and 5, each pair of apertures 10 in the webs 4 of two juxtaposed rope elements has connected thereto two diagonals 3, one in each opening 10. The diagonals (3) are intercalated in each case between a reinforcing plate (22) and the web (4). One of the diagonals of each pair is attached to the rope element by means of a bolt 21 and a nut 21a, while the other is held in position between the rope plate 22 and the rope 21 (4) by means of a pin (35) extending through each of the apertures (10), the hole in the end portion (8) of the diagonal (3) and the aperture (24) in the reinforcement plate.

As can be seen in fig. 5, when the pre-fabricated assemblies are juxtaposed to secure them together, each of the bolts (21) extending through one of the rope members is aligned with a bolt (35) on the other.

When it is desired to secure the rope elements together, the bolts 35 are withdrawn and the rods 20 are pushed out of the spindles 21 through the apertures and aligned holes which were occupied by the bolts, (21b).

By providing the bolts (35) instead of screws in one of each pair of apertures (10), the rope elements can be fastened to each other more quickly, since there are fewer nuts to loosen the bolts and, in addition, rope can be more properly aligned before securing them, so that there is less likelihood of misalignment of the reinforcement plates, diagonals and webs during introduction of the rods (20) into the now vacant holes and openings. In addition, the pins 35 may be pushed out of place by the rods 20 of the screws 21 as the rope members are joined. -10-

The three-dimensional structure according to the present invention further comprises upper (30) and lower (31) shoring elements, the upper shoring elements (30) being fixed to and above the upper strand structures and lower shoring members (31). ) and below the ropes of the lower rope structure, the shorting elements (30) and (31) extending transversely with respect to the ropes and being offset laterally relative to one another.

The shoring elements 30 and 31 are secured to the ropes in positions along their length in which the apertures 10 are provided in the webs 4 thereof. Thus, the shoring elements 30 and 31 cross the ropes in positions where the diagonals 3 are attached to the rope element 1 and 2 of each rope structure.

Each of the shoring elements 30 and 31 is secured to at least two of the ropes in the respective rope structure to which the shoring element is attached.

Structures of various different shapes and forms of subunits may be constructed from prefabricated assemblies of the type described and it will be understood that individual integral parts of the three-dimensional structure may have other constructions other than those described without that we depart from the scope and spirit of the present invention. -11-

For example, the rope elements 1 and 2 may have other shapes than the U-shaped profile, showing Fig. 6 is part of a three-dimensional structure in which the rope elements (1) and (2) are corner elements.

Further, Fig. 6 shows a further embodiment of the present invention in which fasteners are used to fasten together the rope elements 1 and 2 and separate fasteners connect the diagonals 3 to the rope elements 1 and 2) . It will be understood that separate means may be used to connect the diagonals to the ropes and to connect the rope elements (1) and (2) to one another also in a three-dimensional structure with rope members formed by U-shaped sections. Furthermore , while Fig. 6 shows the diagonal 3 attached to a flap 50 of the rope element which is perpendicular to its web 45, the diagonals 3 could be connected to and between the rope elements 1 and 2, promoting instead their connection to souls (45). On the other hand, the diagonals 3 could be attached to these webs 45 at positions other than the positions of the apertures in the webs 45, whereby pairs of rope elements in a given rope structure could be connected together. Other such apertures could be provided in the web (45) to connect diagonals (3). FIG. 7 shows part of yet another embodiment of the present invention in which the rope elements 1 and 2 each comprise elongate U-shaped members in the first and second sections of the rope,

which provides a first side flap (60) inclined relatively to both an intermediate web (65) and a second side flap (70). In such a three-dimensional structure, the diagonals (3) do not need to have inclined end portions with respect to one their middle part, but the resulting three-dimensional structure further comprises upper and lower rope structure ropes mutually offset laterally.

Thus, regardless of whether the rope members are in the shape of U-shaped or angled or otherwise severed shapes, the same means may be used to secure the rope elements together to form strings and to connect the strands to the strings. (I.e.

If desired, diagonals with a construction and configuration other than those described may also be used.

In addition, the shoring elements may be attached to the ropes in the respective rope structures by any suitable means, such as screws or by welding.

Referring to Fig. 8, another embodiment of a three-dimensional structure according to the present invention is shown, comprising rope elements (1) and (2) spaced apart and connected by a number of diagonals (3). There are shortening elements (30) and (31) extending transversely

in relation to the rope elements (1) and (2). The diagonals 3 are connected to the rope elements 1 and 2 by means of connectors 100 comprising a number of plates 101 and 102 which are connected together to form an integrated whole and which are inclined relative to each other so as to rest within an angle of a rope element 1 and 2 and have plates 101 tilted relative to each other and to sides 200 and 201) of the rope elements (1) and (2) forming an angle. The plates 102 are flat or substantially flat against the sides 200 and 201 of the rope members 1 and 2 that form the angle and provide apertures 103 that can be aligned with provided apertures in the rope elements (1,2) to enable the plates (102) to be attached to the sides (200) and (201) of the rope elements (1) and (2) by means of a screw or similar connecting element which passes through the holes thus aligned. The same or the same screws or other connecting members by means of which the fasteners 100 are fixed to the ropes may also be used to fasten together rope elements 1 and 2, back-to-back, which is shown by a single screw 104 in Fig. 9.

An aperture (105) is provided in each of the plates (101), a screw or the like, for example another fastening member, can be passed through an aperture (105)

connecting with a suitably adapted end of a diagonal 3 to thereby secure the diagonal 3 to the connector 100, Fig. 12 shows one end of a diagonal having an insert 106 therein. The insert 106 is secured to the open end of the diagonal 3 by the provision of an annular cavity 110 in the insert. The diagonal wall 3 is compressed during attachment of the insert 106 so as to protrude into the cavity and holds it against movement within the hollow of the diagonal. A protruding edge (111) of the diagonal (3) is folded inwardly to further secure the insert against the displacement of the diagonal end.

It will be understood that the insert 106 could be attached to the diagonals 3 by any means other than those described above, for example by the process disclosed in prior art British Patent No. 2 169 678. Moreover, the attachment could be removable rather than permanent. The insert 106 includes a threaded bore 107 in which a screw which has been passed through an aperture 105 in a plate 101 of a binder 100 can be received. This is illustrated in Fig. 13.-15-

FIG. 11 shows an alternative arrangement of the rope elements 1 and 2 in which one of each of the pairs of rope elements that are back-to-back and connected to each other comprises sides 300 and 301 which form a angle and flaps 303 and 304 folded inwardly, each of which at its end each has an edge 110. The other of each of the pairs of back-to-back rope elements also comprises angled sides, one of the sides providing a flap (109) which is inwardly facing and the other of the sides providing a flap (108). ) facing outwards, which at its end provides an edge (111). The pairs of rope elements when juxtaposed for mutual connection are arranged such that the flange 108 and the edge 111 overlap the flange 109 and the edge 110 of an adjacent rope element. This facilitates the alignment of the rope elements before and after their interconnection.

It will be understood that this arrangement of the rope members could be applied in the embodiment of the three-dimensional structure shown in FIG. 6 or in the embodiment of the three-dimensional structure shown in FIG. 7.

The characteristics described above in this description, or illustrated in the drawings, expressed in their specific forms or in terms of a means for performing the functions described, or a process for obtaining the indicated results, or a class or group of substances or compositions, as may be may, separately or in any combination of such characteristics, be used for the practice of the present invention in different ways.

Claims (61)

A three-dimensional metal structure having a first strand structure, a second strand structure and a strut and diagonal structure comprising struts and diagonals which hold apart and unite the strand structures, characterized by a strand of struts structures. comprising first and second rope elements connected together side-by-side and said rope elements being connected to ropes of the other rope structure by said diagonal and upright structure. 2. A three-dimensional metallic structure according to claim 1, characterized in that the strands constituting said other strand structure are spaced apart from each other by a greater distance than the separation between the first and second strands. second elements of the ropes constituting a rope in said first rope structure. 3. A three-dimensional metal structure according to claim 1 or 2, characterized in that each rope element in said first rope structures is connected to only one rope adjacent to the other rope structure by means of the uprights and diagonals. air A three-dimensional metal structure according to any one of the preceding claims, characterized in that the ropes in the other rope structure each comprise first and second rope members connected together. 5. A three-dimensional metal structure according to claim 4, characterized in that each rope element in said first chord structure is connected to only one adjacent rope element in the other rope structure by means of the uprights and diagonals. A three-dimensional metal structure according to any one of the preceding claims, characterized in that the color in said first of the strand structures is spaced apart from each other by a distance equal to the spacing between the strands in said other strand structure. 7. A three-dimensional metal structure according to any one of the preceding claims, characterized in that the ropes of the first rope structure extend parallel or substantially parallel to one another. and the ropes of the second rope structure extend parallel or substantially parallel to each other. A three-dimensional metal structure according to any one of the preceding claims, characterized in that the color in the first strand structure extends parallel or substantially parallel to the strands of the second strand structure. 9. A three-dimensional metal structure according to any one of the preceding claims, characterized in that the first strand structure is positioned above the second strand structure with respect to a surface on which or on which the three-dimensional metal structure extends. 10. A three-dimensional metal structure according to claim 9, characterized in that the ropes in the first strand structure are laterally offset from the ropes in the second strand, second strand structure. 11. A three-dimensional metal structure according to any one of the preceding claims, characterized in that the rope elements of a rope are connected to each other by fastening means, each of which extends through and between the rope elements. A three-dimensional metal structure according to any one of the preceding claims, characterized in that the diagonals extend obliquely between adjacent ropes in the first and second rope structures. 13. A three-dimensional metal structure according to any one of the preceding claims, characterized in that the uprights and diagonals each comprise an element having a straight rectilinear portion and end portions which are substantially parallel to one another and which extend in opposite directions moving away from the middle. ' 14. A three-dimensional metal structure according to claim 13, characterized in that each of the end portions of an upright or diagonal is provided with a bore through which a connecting member is received by means of which the upright or diagonal is connected to a rope. -21- 15. A three-dimensional metal structure according to claim 13, further comprising reinforcement plates each of which provides a bore extending therethrough and through which a connecting member is received. 16. Three-dimensional metal structure according to claim 15, characterized in that each connecting element extends through the hole in a reinforcement plate / through the aperture in the end part of an upright or diagonal and through a rope element of the mode such that the end portion of the upright or diagonal is disposed between the rope element and the reinforcing plate. 17. A three-dimensional metal structure according to claim 15 or 16, characterized in that each of the reinforcement plates is provided with two holes extending therethrough, each of which receives a respective connecting member such that a connecting member extends through an end portion of a first upright or diagonal covered by the reinforcing plate and another connecting member extends through an end portion of a second upright or diagonal, the two end portions being covered by the reinforcing plate disposed side-by-side in positions a short distance along the rope element. 18. A three-dimensional metal structure according to claim 17, characterized in that the end portions of the uprights or diagonals do not overlap each other when attached to the ropes. 19. A three-dimensional metal structure according to any one of claims 14 to 18, characterized in that all connecting members are removable. 20. A three-dimensional metal structure according to claim 19, characterized in that each of the connecting members is a bolt or a bolt. 21. A three-dimensional metal structure according to any one of the claims. 14 to 20, when dependent on claim 11, characterized in that each of the connecting or securing members comprises a common component. A three-dimensional metal structure according to any one of the preceding claims, characterized in that it further comprises upper and lower elongated shoring elements, the upper shoring element being fixed to the ropes and above the ropes of the first rope structure and being the lower shortening elements fixed to the ropes and below the ropes of the second rope structure, are the strut members being transversely in relation to the ropes. 23. A three-dimensional metal structure according to claim 22, characterized in that the upper shoring elements are laterally offset from the lower guide elements. 24. A three-dimensional metal structure according to claim 22 or 23, characterized in that the guide elements are attached to the ropes in positions along the length of the ropes in which the uprights and diagonals are also secured in the ropes. A three-dimensional metal structure according to any one of claims 22 to 24, characterized in that each of the strut members is attached to at least two of the ropes of the respective rope structure to which it is attached. 26. A three-dimensional metal structure according to any one of the preceding claims, characterized in that each of the rope elements is constituted by an elongate element with a U-section. 27. Three-dimensional metal structure according to the invention Claim 26, characterized in that the rope elements in a rope are secured to one another in such a way that their U-shaped profiles are facing each other. 28. A three-dimensional metal structure according to claim 26 or 27, characterized in that each upright or day is connected to a rope element on a surface thereof which defines an inner face of the U-shaped profile. A three-dimensional metal structure according to any one of claims 1 to 28, characterized in that each rope element is constituted by an elongated angle. The three-dimensional metal structure according to any one of claims 1 to 20 or 22 to 29, when dependent on any one of claims 1 to 20, characterized in that the uprights and diagonals are connected to a first flap of the rope element by organs. and the rope members are connected to one another by means of securing members extending through a second flap of the rope element. 31. A three-dimensional metal structure according to any one of claims 1 to 27, characterized in that the U-shape is defined by first and second side flaps of the rope element interconnected by an intermediate web, are the first side flap being spaced apart from the intermediate web at an angle different from 90 ° to the latter. 32. A three-dimensional metal structure according to claim 31, characterized in that the second side flap is perpendicular to the intermediate web. 33. A three-dimensional metal structure according to claim 31 or 32, characterized in that the second side flaps of two rope elements are adjacent to one another and are substantially parallel to one another when the rope elements are fixed to each other. to form strings and in that their first side flaps provide means for permitting attachment of the struts and diagonals thereto. 34. A three-dimensional metal structure according to any one of claims 31 to 33, when dependent on any one of claims 1 to 12, characterized in that each of the uprights or diagonals comprises an element having a rectilinear mean and terminal portions which are parallel to a longitudinal axis of the middle portion, each of the end portions each providing an aperture through which a connecting member is received in which the upright or diagonal is attached to a rope. 35. A three-dimensional metal structure according to any one of claims 1 to 12, or 22 to 29, when the teeth of any one of claims 1 to 12 are dependent, characterized in that each of the uprights or diagonals provide at each of their longitudinal ends an insert which is adapted to receive a portion of a connecting member by means of which an upright or diagonal is connected to a rope. 36. A three-dimensional metal structure according to claim 35, characterized in that the included part or the included parts are detachably provided at an upright or diagonal end. 37. A three-dimensional metal structure according to claim 35 or 36, when dependent on claim 29, characterized in that the angle is defined by a first and second side flaps of the rope element, the first and second flanges . at an angle of less than 180Â ° to one another. 38. A three-dimensional metal structure according to claim 37, further comprising an adapter device providing an aperture through which a connecting member may be passed for reception in an included part of an upright or diagonal, extending longitudinally of the aperture obliquely relative to each of the three planes perpendicular to each other in two of which are the first and second side flaps. 39. A three-dimensional metal structure according to claim 38, characterized in that the adaptation means includes a second aperture, the axis of which. longitudinally extends obliquely in relation to each of the three planes perpendicular to each other in two of which, if. first and second flaps and extending at an angle with the longitudinal axis of the aperture. A three-dimensional metal structure according to claim 38 or 39, characterized in that the adaptation means provides a further opening for receiving a second attachment member for the removable attachment of the means for adapting to a rope element. 41. A three-dimensional metal structure according to claim 40, characterized in that the adaptation means comprise a number of plate-shaped parts which form a certain angle with respect to one another to seat a U-shaped profile of a rope element , the one of the plate-like plates providing the aperture, the second piece of plate providing the second aperture and a second aperture-shaped piece of aperture. 42. A three-dimensional metal structure according to any one of claims 1 to 29, characterized in that it comprises a prefabricated assembly according to any one of claims 43 to 56. 43. A prefabricated assembly for use in a three-dimensional metal structure, characterized in that it comprises two strand members spaced from one another and connected together by uprights and diagonals extending obliquely between the other strands, the strands being parallel between if and by providing fastening means by means of which the prefabricated assembly can be secured to another prefabricated element. 44. A prefabricated set according to claim 43, characterized in that the rope elements each provide fastening means, so that when the two rope elements are connected to corresponding rope elements of a rope another prefabricated assembly, a longitudinal axis of one of the rope members is intersected, in its entire length, by a first plane, a longitudinal axis of the other rope element is intersected, throughout its length, by a second plane parallel to and remote from the first plane, and the longitudinal axis of said first plane of the rope elements 29- i is also intersected along its entire length by a third plane and the longitudinal axis of said other rope element is intersected along its entire length by a fourth plane, the third and fourth planes being perpendicular to the first and second and away from each other. 45. A prefabricated assembly according to claim 44, characterized in that the fastening means on said first rope element has a longitudinal axis which is intersected by one of the first and second winding elements. third planes and the securing means on the other. rope elements have an axis which is intersected by one or more of the second and fourth planes. . (I.e. A prefabricated assembly according to any one of claims 43 to 45, characterized in that connecting members and reinforcing plates are provided by means of which the uprights and diagonals are connected to the rope elements so that end portions of two uprights or diagonals are sandwiched between a rope element and a reinforcing plate and the terminal portions of the uprights or diagonals do not overlap one another. A prefabricated assembly according to claim 46, characterized in that each of the uprights or diagonals is constituted by a substantially rectilinear element the parts The ends are substantially parallel to each other and are folded away from the upstream or diagonal portion in opposite directions therefrom, each of the end portions each providing an aperture through which a linking member is received. 48. A prefabricated assembly according to any one of claims 42 to 47, characterized in that the securing means are constituted by fastening members which extend through the rope elements. 49. A prefabricated assembly according to any one of claims 46 to 48, characterized in that each reinforcing plate provides a bore extending therethrough and through which a connecting plate can be received. A prefabricated assembly according to any one of claims 47 to 49, characterized in that each reinforcement plate is provided with two holes extending therethrough, each of which receives a respective connecting member, so that a connecting member extends through an end portion of a first upright or diagonal covered by the reinforcing plate and another connecting member extends through a terminal part of a second upright or diagonal, the two end portions covered by the reinforcing plate arranged side-by-side in positions slightly apart along the rope element. A prefabricated assembly according to any one of claims 48 to 50, characterized in that each of the connecting members is removable. A prefabricated assembly as claimed in claim 51, characterized in that each connecting member is either a screw or a screw. a pin. 53. - Primed assembly according to one of the preceding claims. any of claims 48 to 52, characterized in that each of the connecting members comprises a common component. ^ A prefabricated assembly as claimed in any one of claims 42 to 53, characterized in that. for each of the. The rope elements are constituted by an elongate member with the U-section. 55. A prefabricated assembly according to claim 54, characterized in that each of the uprights or diagonals is connected to one side of the ropes defining an inner face of the U-profile. A prefabricated assembly according to any one of claims 42 to 53, characterized in that each of the rope elements is constituted by an elongated member in the form of a can- tone. 57. A method of constructing a three-dimensional metal structure comprising a number of interconnected primary and secondary arrays, each assembly comprising two interconnected rope and diagonal members, characterized in that it comprises the steps of: juxtaposing two arrays of arrays. so that a rope element of one of the assemblies is situated side-by-side with a rope element of the other of the assemblies and connecting the assemblies together. 58. A method according to claim 57, characterized in that it comprises the step of connecting between the rope elements of each set situated side-by-side. 59. - Process of. according to claim 57 or 58, characterized in that the prefabricated assemblies are sets according to any one of claims 43 to 56. A method according to claim 59, as dependent on claim 52, characterized in that: further comprising the steps of: juxtaposing two assemblies so that the sides of rope elements, facing the opposite side of the one to which the uprights or diagonals are connected, are adjacent one another, and so that the rods of each bolt that secures the upright or diagonally to a rope extend towards an aligned hole in the adjacent rope, that hole being capped with a bolt, push the bolts outwardly and receive the bolts of the bolts. bolts through the holes, having these bolts been previously engaged, and tightening a nut on the protruding studs of the bolts to secure them. 61. - Process according to a. any of claims 57 to 60, characterized. by further comprising the step of juxtaposing a further assembly with the composite assembly of two assemblies and securing the same in those assemblies, and securing to the composite assembly other pre-fabricated assemblies until a three-dimensional metal structure of the desired size and shape is constructed. A method according to any one of claims 57 to 61, characterized in that it comprises the step of positioning strut members transversely with respect to the strings, the strings being in the upper position in the composite, at places along the strings which are adjacent to places where the strings and diagonals are attached to the strings and to fasten the strings to the strings. A method according to any one of claims 57 to 62, characterized in that it further comprises the step of positioning The strings being in the lower position in the composite at locations along the strings adjacent the places where the struts and diagonals are attached to the strings and securing the struts on the ropes. Lisbon, 4 October 1990 CHdcú of Industrial Property