PT108990A - TRIANGULAR MODULAR STRUCTURAL SYSTEM FOR COUPLING IN LEVELS - Google Patents

Abstract

The present invention relates to a modular system of monolithic polyurethane structural elements, applicable to the development of horizontal or horizontal functional structures, which is directed to the framework at the level of structures or in the horizontal or rectilinear or circular surfaces, through the coupling SUCCESSIVE OR COMBINED AND IDENTICAL OR DIFFERENTIATED FROM THEIR TWO BASIC COMPONENTS, THE POLY DRUG CHANFER (2) AND THE TRIANGULAR BLADE (1) WHOSE TUBULAR BASE OF THE BLADE (13) FITS SIDE SLIDE INTO THE POLYURIC CHANFRO BASE (2) WILL IN YOUR (6) for horizontal coupling, whereby the successive coupling of the elements is determined by the union between the said polyhedron chambers (2) by means of the external cylinder (12) ) IN THE CYLINDRICAL INTRUSION (8), WANTS BETWEEN TRIANGULAR BLADES (1) BY INTRODUCTION OF THE TUBULAR SLIDE OF THE BLADE (1) 4) IN THE TUBULAR BLADE OF THE BLADE (15).

Description

Description

Technical Field of the Invention

At present manufacturers of transitional systems for the installation of dynamic auxiliary supports - fixed or mobile - to operational activities, structural support of materials and equipment, and temporary physical coverage of installations, goods and persons, whether in the domestic or industrial environment or in the public domain, have placed on the market this type of products that are too standardized to the activities and in a somewhat discretionary way on objective clienteles, recurrently directed to ends, services and incisive uses resulting from the demands of increasing functional and technical specialization. The technical origin of these types of product solutions is already highly specialized - particularly small structures of pipe scaffolding, plating fences, metal or plastic sheet coverings, stretched fiber or fabric pavilions or tents, movable pillars or columns, walkways or platforms and industrial shelves and other standard systems - reports the need to construct or quickly assemble a versatile and adaptable structure, dynamic but stable, where to support, relocate or provide coverage of people, goods and equipment, said structure also having the capacity to complement and adapt to the fundamental root structures already existing in the market. Called to perform essential immobilization functions as a stable support with easy handling and transportability, low scientific complexity and a reduced number of basic components, the technical area of these structural systems thus encompasses the region of the frame or fast construction of certain mechanical components which, according to special and distinct characteristics of their design, composition and production that enable them to create an interim or definitive parallel artificial arrangement capable of being quickly demobilized and transported to any place.

State of the art

Due to the fact that markets on the supply side - that is, industrial production or assembly of the constituent elements of these structures - are deeply regulated and therefore also well-known for their purpose, it is easier to truly generalist, multifunctional and flexible systems in integrated standard part assemblies, for example, in construction toys or architecture for young children. Subsequently, products traditionally overweight or too many components that are easily lost and difficult to replace - tend to over-metallize their basic elements, limiting both their diverse functionality and complementarity, when one intends to adapt those to other elements physical and / or mechanical by arbitrary matching in perfectly timely and random situations.

SUMMARY OF THE INVENTION The present invention relates to a mountable polyvalent system with a triangular predominant architectural geometry applicable in the development of horizontal and / or level framework structures by successive or differentiated coupling of its two polyhedral components (2), and the thick and massive triangular blade (1), both of which have standardized dimensions depending on the purpose, and the third general element with a tubular shape - the outer cylinder (12), which functions as a pliable, malleable, sturdy and compact, structural engaging tube, aggregator of said two basic components, this invention being described as naturally directed to the edification at the level of structures or horizontally of surfaces or platforms rectilinear or circular.

With only three such constituent elements, this system was conceived to be potentially universalist and generalist as possible - as regards its general geometrical form of framing - however with dimensions not defined in the concrete, these being standardized to the objectives proposed for each intended application . A symbiosis of ergonomics (adaptability to various functions), ergodicity (almost invariance to the initial geometry of the parts) and complementarity (without replacement, it helps other existing systems of structures by fitting or assembly of geometric elements). In the present case involving metallic pipes arranged in scaffolds, these parts do not in themselves allow the structuring of surfaces, however, said triangular blades (1) engaged in an inverted manner with each other and these to said polyhedral bevels (2) are coupled to fit into said pipes and form platforms. Thus, the components of the invention - with an emphasis on the said outer structural coupling cylinder 12 - can be readjusted in their original design and modified in their dimensions to even be allowed as a self-contained system.

Another feature is the architectural flexibility of the system in that only three of its constituent elements (1,2,12) can be assembled with a universal number of structures, such as tents and tents, fences or partitions, wall and side protections, straight and curvilinear treads, sidewalks and paths, general floor and level (high or uneven), coverings and shelter materials, platforms and scaffolding, covers and tops, tables, chairs and benches, support bases, frames and shelves, structural elevations and walls, tiles and special masonry, among many other uses. The present invention therefore provides a modular triangular system of mountable multifunctional structural elements applicable in the development of horizontal or tiered functional structures, typically directed to the frame at vertical level of structures or horizontally of rectilinear or circular surfaces or platforms, (2), and the triangular blade (1) whose tubular base of the blade (13) is slidably fitted in said polyhedral groove (2) by means of the successive or combined and identical or differentiated coupling of its two basic components, in one of its two cylindrical cuts is the upper cylindrical cut (4) for level coupling or the front cylindrical cut (6) for horizontal coupling, whereby the successive connection of the elements is effected either by the union between said polyhedral bevels (2) ) by engagement of the outer cylinder (12) in the cylindrical intrusion (8), or between blade the triangular ones (1) by introducing the tubular side of the blade (14) into the tubular intrusion of the blade (15). The present invention is hereinafter described in detail, without limitation and by way of example, by means of a preferred embodiment thereof, shown in the accompanying drawings with associated nomenclature, in which: - figure 1, identical to the figure for publication, presents the components of the system and integrates the types of docking and docking between them; Figures 2 and 3 show, in relation to Figure 1, the architectural ergonomics, complementarity, ergodicity and flexibility characteristics of the system without substantially altering the geometry of its components; Figures 4 and 10 show the individualized components, depicted in relief in their most important details; - Figure 5 describes the procedures for the basic joints and couplings between triangular blades (1), between polyhedral bevels (2) and the same blades, to the same bevels, with unchanged ergodicity of the basic parts, and - Figures 6 to 9 represent the technical characteristics consolidated in structures typified by means of frame and successive fitting of the elements of the system.

Thus, the nomenclature associated with the figures - possibly abbreviated in the expositions - is as follows: 01 Triangular blade; 02 Polyhedral bevel; 03 Concave angular projection; 04 Upper cylindrical cut; 05 Angular bisector; 06 Front cylindrical cut; 07 Convex angular projection; 08 Cylindrical Intrusion; 09 Rear of the chamfer; 10 Bevel base; 11 Bevel side; 12 External cylinder; 13 Tubular base of the blade; 14 Tubular side of the blade; 15 Tubular Intrusion of the Blade; Filament laminar filament; 17 Tubular gap for filament fit; 18 Blade Focus.

DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring now to the figures, the preferred embodiment of the invention will now be described in which the modular triangular-shaped modular system for level coupling is constituted by a set of 3 elementary parts having functional reliefs on their faces and which are shown in said figures it is demonstrated how the said pieces are coupled as described below in order to achieve a functional and stable structure depending on the composition proposed in their genesis architecture. The demonstration of length measurements of the present system is irrelevant and falls outside the scope of this document, but it is important to note that, in general, the alteration and fixation of the dimensional parameters and the characteristics of the basic elements, reshape the geometry of the system itself structure to be designed and allow an adaptation of the triangular system to the most varied purposes and applications. Said modular structural system is composed of 3 standard elements or parts, namely the triangular blade 1 which constitutes the surface component, the polyhedral bevel 2 as the structural support member and the outer cylinder 12 as a component of structural engagement which in the present model of figures is presented with a solid and rectilinear tubular shape, without bending or angular perpendicular in its general form.

SUMMARY OF THE INVENTION Generally, the present invention is concerned with a mountable polyvalent system, applicable in the development of horizontal or level functional structures, by framework, by overlapping or by joining, by successive or differentiated coupling of the two basic components, fabricable in semi-solid matter and flexible, ergonomic, sturdy and ultra-light, typically oriented to the framework at the level of structures or horizontal surfaces or rectilinear or circular platforms. Said system comprises the massive triangular blade (1) of standard dimensions, the natural base of which has a tubular extrusion called the tubular base of the blade (13) which fits - by lateral sliding - in the polyhedral groove (2) within its upper cylindrical cut (4) for level frame or front cylindrical cut (6) for horizontal frame. The successive coupling of identical elements is effected by the connection between the polyhedral grooves (2) by engagement of the outer cylinder (12) in the cylindrical intrusion (8) and by the joining between the triangular blades (1) sliding of the tubular side of the blade (14) into the tubular intrusion of the blade (15), according to Figures 1 and 5. The polyhedral support bevel (2) of structural support has two longitudinal cylindrical tubular cuts dug on its surface between the two (4), which is positioned on the upper face of the polyhedral groove (2) between the protrusion (4), which is positioned on the upper face of the polyhedral groove (2) between the protrusion (3) and the angular bisector (5), allows to be engaged by the tubular base of the blade (13) by insertion with later lateral displacement, which defines the process of engagement to the chamfer vertically or which level provides angular elevation of said triangular blade (1) in a cyclic interval of almost 180 ° of rotation, but never parallel to the ground that is horizontal as it is limited by said angular bisector (5). The front cylindrical cut 6 - identical to the upper cylindrical cut 4 - defining and positioning on the front face of the polyhedral bevel 2 between the angular bisector 5 and the convex angular projection 7 allows it to be engaged by the tubular base of the blade (13) by insertion with later lateral displacement defining the engagement process to the horizontal chamfer, according to Figures 4 and 5. Likewise, according to Figure 4, said cylindrical cuts (4,6 ) allow to be engaged by the same process by the outer cylinder (12) as they have equal diameters.

In terms of surface worked reliefs, the polyhedral chamfer (2) has a concave angular projection (3) shown as concave in the angular limit between the rear face of the chamfer (9) and said upper cylindrical cut (4) and another convex angular projection (7) shown as convex at the angular limit between said front cylindrical cut (6) and the surface of the base of the chamfer (10), according to Figures 3 to 5 and 10.

If the successive joining is side by side concatenation between the triangular blades (1) supported by said polyhedral bevels (2), it is processed in such a way that they are identically oriented vertically towards the same direction ie their foci (18) pointing to a converging point, a conical regular conical surface is obtained whose number of sides of its base - i.e. the number of polyhedral bevels 2 when joined together and these to the tubular bases of the blades 13, by the upper cylindrical cut 4 - is directly proportional to the measure of the regular height of the triangles defining said triangular blades 1. With the orbicularisation of said conical structure, a new compressed focus of the resulting spiral is obtained, located in the upright peak composed by the junction of said foci of the blades (18), which seals said structure, according to figures 1, 3 and 5.

By means of the repeated horizontal union, that is to say, concatenation between the triangular blades (1) converging simultaneously towards the same direction of alignment of their foci of the blades (18), a circular surface is obtained with the orbital conclusion, which is receivable by said chamfers (2) by engagement of respective tubular bases of the blades (13) to the upper cylindrical cuts (4) or cylindrical cuts (6), according to figures 2 and 5 to 7.

When the successive joining, ie, side-by-side concatenation between the triangular blades (1), is effected in such a way that their foci of the blades (18) are differently oriented in opposite directions, ie alternating both vertically and horizontally, is obtained a rectangular surface which is the base for the frame of rectangular structures or platforms, according to Figures 1, 2, 5, 8 and 9. In the horizontal plane to the ground, the joining of said triangular blades (1) oriented in alternate directions forms straight and flat surfaces of stability and connection between distinct points according to Figures 8 and 9 whereas in the vertical plane the same type of connection generates flat or corrugated partitions precisely of interruption or separation between spaces, according to figure 2. 0 degree of perpendicularity of the generated rectangular surfaces depends on the angular characteristics of said triangular blades (1) in their design. In both cases, if said triangular blades (1) are attached to the polyhedral grooves (2) by their tubular bases of the blades (13), said rectangular surfaces remain edged and reinforced in their stability. The standard process of lateral joining of two polyhedral grooves 2 occurs by introducing the outer cylinder 12 - shown in its rectilinear shape - into the cylindrical intrusions 8 in connection with which the tubular holes are formed longitudinally dug between the two side of the chamfer 11, according to Figures 3 to 5. Said cylindrical intrusion 8 is demarcated and starts at the central diagonal point of the residual area on each said side of the chamfer 11, short of said upper cylindrical cut 4) and front cylindrical cut (6), running along the longitudinal extent of the polyhedral bevel (2). The outer cylinder 12 has a standard length not greater than the distance between the sides of the chamfer 11 and its thickness is ordinarily equal to the diameters of the upper cylindrical cut 4, frontal cylindrical cut 6 and intrusion (8), less an infinitesimal gap allowing the introduction of said outer cylinder (12) therein. The triangular blade (1) has a cylindrical extrusion on the natural side of the base of the triangle defining it, which forms the tubular base of the blade (13) which protrudes along the entire length of said base of the triangle and projects between the natural alignments of the two areas of the opposing surfaces of said triangular blade (1), the thickness of its resilient circular is identical to that of the outer cylinder (12) for engaging the upper cylindrical cuts (4) and the front cylindrical cut according to Figures 4, 5 and 10. On one of the two auxiliary sides of the body of the triangular blade 1 protrudes over the entire length of said side the tubular side of the blade 14 which projects between the natural alignments of the two opposing surface areas of said blade, but with a thickness less than that of the tubular base of the blade (13). Symmetrically, on the remaining auxiliary side of said triangular blade (1), the tubular intrusion of the blade (15) whose diameter is equal to that of said tubular side of the blade (14) is dug in its thickness along the entire extent of said side. ) in order precisely because it is engaged. Said tubular intrusion of the blade 15 persists even in the protruding mass of said tubular base of the blade 13 as shown in Figure 10, until the corresponding cylindrical aperture is obtained. At the tip of the focus of the blade 18 is the tubular filament filament 16, as well as the tubular gap for engaging the filament 17 which separates the mass from said tubular side of the blade 14 of the body (1), which clearance allows the engagement of the body of said tubular side of the blade (14) within said tubular intrusion of the blade (15), to the competition and below said laminar filament of said blade (16) which secures the insurgent tube, according to Figures 4, 5 and 10. At the opposite end of said tubular side of the blade (14) next to the tubular base of the blade (13), a further tubular gap occurs for engagement in the (17) with more accurate accuracy shown in Figure 10. Said tubular filament filament (16) enhances the technical consistency and strength of the blade focus (18) in both conical and circular unions as well as in rectangular, according to Figures 2, 3 and 6 to The process of vertical engagement with the polyhedral bevel (2) occurs when the tubular base of the blade (13) is inserted laterally at one of the two ends of the upper cylindrical cut (4) affixed to the upper face of said bevel by sliding from a from the sides of the bevel (11) to the competition of the other opposite opposite end. The method of horizontally engaging the polyhedral bevel (2) occurs when said tubular base of the blade (13) is inserted laterally at one of the two ends of the front cylindrical cut (6) affixed to the front face of said bevel just above the convex angular protrusion (7) by sliding from one side of the bevel (11) to the competition of the other corresponding opposite end, according to Figure 5. The methodology of lateral bonding iterated between two triangular blades (1) is executable according to two distinct processes . In order to concatenate a circular conical surface, it is important that said triangular blades (1) are positioned side by side and with their foci of the blade (18) oriented in the same direction, which begins with the introduction of said tubular side of the blade (14) adjacent said blade center (18) of the first triangular blade (1) inside and sliding into the tubular intrusion of the blade (15) near the end of its tubular base of the blade (13) of the second triangular blade (1) , the engagement remaining to the competition of said tubular gap for engaging the filament (17) of the first in said tubular filament filament (16) of the second. Symmetrically, in order to concatenate a rectangular sectional surface, it differs only from the previous process in which the joint between two triangular blades (1) opens with its two foci of the blades (18) now oriented in opposite directions, whereby said first triangular blade (1) initiates engagement precisely along its own tubular base of the blade (13) against said tubular base of the blade (13) of the second, i.e. by inserting the tubular side of the blade (14) from the first inwardly and sliding in the (15) of the second, until the competition of said tubular gap for engaging the filament (17) of the first in said laminar filament filament (16) of the second, as evidenced in Figure 5.

10, the polyhedral grooves 2 may be longitudinally joined together by either direct insertion with pressure or by sliding insertion of both the concave angled projections 3 and the resilient convex angular projections 7, within said upper cylindrical cuts 4 or front cylindrical cuts 6, engaging parities between said bevels using the nomenclature of said cutbacks referred to with feasible combinations of type (4,4), (4,6) and (6,6). Although this type of joining is not as robust as required, it nevertheless permits longitudinal arching of said polyhedral grooves (2) and, by successive couplings, to construct small structures such as benches, barriers and trenches for slopes or slopes in land, partitions, pedestrian boundaries, , fast supports and bases of support, steps and stairs, among others. Subsequently, the accumulation of the flexibility of the gaps along these successive vertical notches of said chamfers also allows, along with its longitudinal arching, a lateral arching or circularity of the forming structure, in order to construct a screen or sheet which is capable geometric orientation along the geodetic relief of the surfaces where they are implanted.

Mode of the invention

The most common realization and production techniques for this type of elements are based on the construction and use of molds for injection of the substance of the raw components, these being later adapted to the dimensions and morphology required by the markets through transformation operations in programming environment and computerized machining. The type of usable substance must have basic characteristics of flexibility and malleability, impermeability, lightness, relative density and hardness, and active resistance to constant use.

Industrial applications The possible uses of a wide variety of human and physical supports for extraordinary, risky or rapid wear are abundant and universally known. The triangular system can quickly provide structures to assist and equip ambulatory vehicles, hospitals, general civil and military transportation. It can be used in military or humanitarian campaigns to accommodate populations in catastrophic areas or to assist in the dynamic stabilization of people and equipment during industrial manufacturing processes in which impacts and vibrations that regularly put people and property at risk occur. It is a system that is essentially suitable for generating, adapting or improving generic structures - such as scaffolding, fences and fences, roofs, protections, tents or pavilions, dynamic pillars or columns, walkways, platforms or general shelves, among other standard systems. the accommodation of people and goods in the exercise of functions in specific labor, social or housing activities.

Vermoil, March 17, 2016

Claims (17)

Claims A modular structural system of triangular shape for coupling at levels, characterized in that it comprises three elementary components, namely the polyhedral structural bevel (2), the outer structural cylinder (12) and the structural surface triangular blade (1) whose tubular base of the blade (13) is slidably fitted in said polyhedral groove (2) either in its upper cylindrical cut (4) for level coupling or in the front cylindrical cut (6) for horizontal coupling, wherein the coupling (2) by engagement of the outer cylinder (12) in the lateral opening of the corresponding cylindrical intrusion (8), or by the union between two triangular blades (1) by introduction of the (14) of the first in the tubular intrusion of the blade (15) of the second. A system according to claim 1, characterized in that the polyhedral bevel (2) has three longitudinal intrusions ie tubular structural coupling cylindrical cuts, dug and extruded from the surface, namely the upper cylindrical cut (4) for level engagement (6) for lateral or horizontal engagement located on the corresponding front face, and the cylindrical intrusion (8) for engaging the outer cylinder (12) demarcated at the central diagonal point of the mass below said cylindrical cuts (4,6) between the two sides of the chamfer (11). System according to claims 1 and 2, characterized in that the cylindrical cuts (4,6) can be coupled to the triangular blades (1) by introducing the tubular base of the blade (13) by direct pressure or by a lateral displacement , allowing an angular rotation of said triangular blade (1) in a cyclic range of less than 180 ° limited by the concave angular projection (3), convex angular projection (7) and the angular angular bisector (5). System according to claims 1 and 3, characterized in that the polyhedral bevel (2) has bevelled relief on its surface two rounded longitudinal projections, namely the concave angular projection (3) shown as concave in the angular limit between the rear of the (9) and the upper cylindrical cut (4), and the convex angular projection (7) shown as convex at the angular limit between the front cylindrical cutout (6) and the base of the chamfer (10). A system according to claims 1 and 2, characterized in that the outer cylinder (12) can have standard sizes and shapes having a thickness identically dimensioned to the single diameter of the cylindrical cuts (4,6) and the cylindrical intrusion (8), in order to allow the coupling between polyhedral bevels (2). A system according to claims 1 and 3, characterized in that the triangular blade (1) has, on the side of the seat perpendicular to the triangle defining it, a cylindrical extrusion ie the tubular base of the blade (13) protruding over of the entire extent of said seat, which projects between the natural alignments of the two opposing surface areas of said triangular blade (1) and whose thickness is identical to that of the outer cylinder (12) and infinitesimally inferior to that of the cylindrical cuts (4). , 6) where you want to engage. A system according to claim 1, characterized in that, on one of the two auxiliary sides of the triangular blade (1) protruding over the entire length of said side, a cylindrical extrusion i.e. the tubular side of the blade (14) whose diameter is less than that of the thickness of said triangular blade (1) and is identical to that of the tubular intrusion of the blade (15) where it is intended to engage. A system according to claims 1, 6 and 7, characterized in that on the remaining auxiliary side of the triangular blade (1) it is dug inside its thickness and over the entire extension of said side, a cylindrical boss, that is the intrusion (15) which even persists in the resilient mass of the tubular base of the blade (13) until the consequent cylindrical opening is completed, and whose diameter is identical to the thickness of the tubular side of the blade (14) where it is intended to engage. A system according to claims 1, 7 and 8, characterized in that the cylindrical body of the tubular side of the blade (14) has, at each of its two end points, a short intersectional gap i.e. the tubular gap for engagement in the (17) which separates said tubular side of the blade (14) from the main body of the triangular blade (1). A system according to claims 1 and 7 to 9, characterized in that the triangular blade (1) has, in the spout ie in the extreme limit of its focus of the blade (18), the tubular filament filament (16) which connects the resilient ends of the tubular intrusion surrounding mass of the blade 15, but also separates from the tubular side body of the blade 14 via the tubular gap for engaging the filament 17. System according to claim 1 and 7 to 10, characterized in that the lateral joint between two triangular blades (1) can be executed in such a way that their foci of the blades (18) are identically oriented in the same conical direction, which process begins with the introduction of said tubular side of the blade (14) next to said blade focus (18) of the first triangular blade (1), and sliding in the tubular intrusion of the blade (15) near the end of its base (13) of the second triangular blade (1), the engagement remaining to the competition of the tubular gap for engaging the filament (17) of the first in the tubular filament filament (16) of the second. A system according to claims 1 and 7 to 10, characterized in that the lateral joint between two triangular blades (1) can be executed in such a way that its foci of the blades (18) are oriented in opposite directions, that is alternating , wherein said first triangular blade (1) begins to engage exactly with its own tubular base of the blade (13) against said tubular base of the blade (13) of the second, that is by inserting the tubular side of the blade (14) (15) of the second, the engagement remaining to the competition of the tubular gap for engaging the filament (17) of the first in the tubular filament filament (16) of the second. A system according to claims 1, 2 and 5, characterized in that the standard process of lateral bonding between two polyhedral grooves (2) is carried out by partially introducing the outer cylinder (12) into the corresponding cylindrical intrusion (8) of each of said chamfers (2) being joined together until the clearance gap between them is extinguished by abutment of the two sides of the chamfers (11). System according to claims 1, 2 and 4, characterized in that the upper cylindrical cut (4) and the front cylindrical cut (6) allow the polyhedral bevelles (2) to be longitudinally joined together, either by direct engagement (3) or the angular convex protrusions (7) inside said cylindrical cuts (4,6), making engagement parity between said bevels (2) with combinations (4,4), (4,6) or (6,6) are possible. System according to claims 1 and 11, characterized in that the lateral iteration process, ie concatenation between triangular blades (1), enables a concentric conical surface to be acquired in the vertical angular plane or a circular concentric surface in the horizontal plane to the ground. System according to claims 1 and 12, characterized in that the lateral iteration process, ie concatenation between triangular blades (1), allows the acquisition of a quadratic surface, both in the vertical angular plane and in the horizontal plane to the ground. System according to claims 1, 11 and 15, characterized in that the orbicularisation of the concatenation between triangular blades (1), either in the form of a conical concentric surface or in the form of a circular concentric surface, enables a compressed focus of the resulting spiral which seals the point of convergence of the foci of the individual blades (18).