ES1297641U - Edge connection system by joining discs for the assembly of polyhedral structures (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Edge connection system through the union of discs for the assembly of polyhedral structures, characterized by being composed of several solid discs, of 1 or 2 sizes and by rail pivots attached to edges with their respective heads at both ends of these ; the largest disc has, along the outside of the circumference of the internal face of its body (2), an L-shaped rail (3); Said larger disk has a smooth hole (5) in the center that crosses it transversally; the union of two larger discs symmetrically on their internal face gives rise to the edge connector, said edge connector has a variable number of rail pivots arranged longitudinally and anchored along the length of the rail in the shape of an inverted T (6) of said connector, The rail pivots consist of a body and a base: the rail pivot bases for joining discs symmetrically (17) are inserted into the desired places on the larger disc rail (3), said bases have the same dimensions in width and height than the inverted T-shaped rail (6) of the edge connector. By joining two larger discs on their internal face and anchoring them by means of a screw that goes through the central transversal hole (5) of both discs and nut, the rail pivot bases are fixed. At that moment, the rail pivot body and the rail pivot base are joined by inserting the pivot base screw (16) through the longitudinal hole with thread (14) of the pivot body, by turning it, leaving the body anchored longitudinally to the edge connector. The body of the rail pivot has a flange (12), with grooves in its internal part arranged radially (15) and a threaded hole that crosses through its center transversally (13). (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

Edge connection system by joining discs for the assembly of polyhedral structures

Technical sector

Design and assembly of polyhedral structures.

Background of the invention

A polyhedron is a geometric body limited by flat faces or polygons. A polygon is a flat geometric figure that is bounded by three or more lines and has three or more angles and vertices. Geodesic domes or domes are hemispherical polyhedral structures composed of a set of joined edges that form triangles. SEE FIGURE 1

The joining points of the edges are called VERTICES or CONNECTION NODES. These vertices or connection nodes in geodesic domes have 6 edge unions SEE FIGURE 2B, 5 edge unions SEE FIGURE 2A, or 4 edge unions at the base SEE FIGURE 2C

The polyhedral figure on which the geodesic dome is based is the ICOSAHEDRON, which is a regular polyhedron formed by 20 equilateral triangles SEE FIGURE 3. The times in which the sides of the Icosahedron triangle are divided are called the DOME FREQUENCY. In figure 3, a frequency 3 is shown.

In FIGURE 4, examples of geodesic domes of different frequencies, but equal dimensions of diameter and height are presented. The higher the frequency, the dome is closer to the semi-spherical shape, it has more triangles to form that semi-sphere and these are joined at different angles according to their frequency. Figure 4 A shows a Frequency 3 geodesic dome, Figure 4 B shows a Frequency 4 geodesic dome, Figure 4 C shows a Frequency 5 geodesic dome, Figure 4 D shows a Frequency 6 geodesic dome.

state of the art

In the current market, geodesic dome assembly companies manufacture specific edge connectors for 6-edge, 5-edge and 4-edge joints, with the manufacturing cost that this entails. In addition, in almost all companies, these connectors have fixed angles corresponding to the frequency to which they belong, so they can only be used for that frequency.

Most existing edge connectors for mounting geodesic domes only allow the use of a specific type of edge, either solid or hollow.

Explanation of the invention

Edge connection system through the union of discs for the assembly of polyhedral structures made up of: SOLID DISCS OF 1 OR 2 SIZES: The edge connector consists of 2 large discs arranged symmetrically and joined on the inside, each disc has a concentric rail on its inner face, said disc has a smooth central transverse hole; the system is also made up of a small disk, with a concentric rail on its face internally, said disc has a smooth central transverse hole of the same diameter as that of the large disc; it is also made up of a rail pivot, formed by a pivot base, of two types, and a pivot body, by edge head, of two types: for tubular edge and for prism-shaped edge; It is also made up of a fixing screw for the rail pivot and edge head; by edges; by anchoring bracket, and by screws of different types to join the edge heads to their corresponding edge and the discs to each other.

BIG DISC

Solid disc SEE FIGURE 5 with a smooth central transversal hole and a concentric L-shaped rail on one of its faces, located along the circumference of the disc: In FIGURE 5: 5A is the front view, 5B is the front view. internal side and 5C is the external side view and where (1) is the external body of the disc, (2) is the internal body, (3) is the concentric rail, L-shaped; (4) are grooves on the internal face arranged radially, (5) is the smooth central hole.

FIG 6 is the cross section of the disc, where (1) is the body of the disc (3) is the outer rail, L-shaped; (4) are the grooves on the internal face arranged radially and (5) is the smooth central hole.

FIG 7 is the cross section of the union in a symmetrical way on its internal face of the two large discs, which gives rise to the EDGE CONNECTOR, where (6) is the inverted T-shaped rail that is formed by the union of the rails of the two discs and where the bases of the rail pivots will be placed to join the discs symmetrically. SEE FIGURE 11. In figure 7: (1) is the body of the large disc, (4) is the radially arranged grooves on the internal face of the large disc, (5) is the smooth central hole of the large disc

SMALL DISC

Solid disc with a smaller diameter than that of the large disc, SEE FIGURE 8 with a smooth central transverse hole of the same diameter as that of the smooth central transverse hole of the large disc, (5) and with a concentric L-shaped rail on one of its faces, located along the circumference of the disk. This rail has the same width and height dimensions as the large disc rail (3). In FIGURE 8: 8A is the front view, 8B is the internal side view and 8C is the external side view and where (7) is the external body of the disc, where (8) is the internal body of the disc, (9) is the L-shaped concentric rail (10) is the smooth center hole, the same diameter as the center hole of the large disc (5)

FIGURE 9 is a cross section of the small disk, where (7) is the outer body of the disk, (9) is the L-shaped rail, and (10) is the smooth central hole.

RAIL PIVOT

It consists of 2 pieces: Body of the pivot and Base of the pivot.

PIVOT BODY: SEE FIGURE 10, where 10A is a front view, 10B is an internal side view, 10C is an external side view, 10D is a top view, and 10E is a bottom view. The body of the rail pivot is a cylinder (11), the middle of which is a flange (12).

This flange is traversed transversally by a threaded hole (13), so that a fastening screw (51) can pass through it, SEE FIGURE 28 and FIGURE 29, which will join the body of the pivot with the corresponding edge head. SEE FIGURE 13 and FIGURE 14

The body has a longitudinal hole at its base with a thread (14), with the diameter of the screw of the rail pivot base for disc union (16) SEE FIG 11 and of the screw of the rail pivot base for individual use of the disc (18) SEE FIGURE 12, to join them. Inside the flange, surrounding the smooth hole, there are grooves arranged radially (15), which will serve to anchor and immobilize the pivot and head joint, with dimensions and arrangement equal to those splines of the tubular head (25) SEE FIGURE 13 and of the splines of the head for prism-shaped edges (32) SEE FIGURE 14

The second element is the PIVOT BASE, which is of two types: for JOINING DISCS IN SYMMETRICAL FORM and FOR SINGLE DISC

THE PIVOT BASE FOR JOINING DISCS IN A SYMMETRICAL FORM to create the edge connector SEE FIG 11, where 11 A is a profile view, 11 B is an elevation view and 11C is a plan view. This base is made up of a rail plate (17) in the shape of the curve of the rail and a screw (16) arranged perpendicular to the plate in its center, with the diameter of the longitudinal hole of the base of the pivot body. rail (14).

There is also the PIVOT BASE FOR THE DISC USED INDIVIDUALLY, FIG 12 where 12A is a profile view, 12B is a plan view and 12C is an elevation view. This base is made up of a body (19), which has a threaded screw arranged perpendicular to the body (18), with the diameter of the longitudinal hole of the base of the rail pivot body (14); (20) is the rail shaped curved tab, which inserts into the disc rail when used individually

Most solutions on the market can only connect a fixed number of edges per connector. With the edge connector formed by joining two symmetrical discs on its internal face, a variable number of edges can be connected to it when assembling polyhedral structures, thanks to the T-shaped rail of the connector (6), the result from the union of the rails (3) of the two symmetrical discs. This rail has the curvature of the base of the rail pivot (17) for joining large discs in a symmetrical way and where a variable number of these bases of rail pivots can be placed in the position that we want from the 360 ° of the rail. of the disc resulting from the union of the rails of the symmetrical discs, to join these bases, first to the rail pivot bodies and then these to the edge heads SEE FIGURE 13 and FIGURE 14. In the case of mounting geodesic domes , this saves the cost of having to manufacture a specific connector for 6 edges, for 5 edges and for 4 edges, if two large disks joined symmetrically are used.

By anchoring the small disk to the junction of two large disks that form the edge connector, on one or both faces of the edge connector, several additional edges per face can be added to this edge connector, thereby increasing the design possibilities of the edges. polyhedral structures and, in the case of geodesic domes, allows the joining of domes of the same or different sizes and/or of the same or different frequencies.

If used individually, both the larger and smaller discs can be anchored to any flat surface by inserting a suitable screw/nail through their central hole: this means flat surfaces such as walls, ceilings, floors, furniture sides can be used , posts, plates of various materials, etc.... Then, joining the corresponding individual disc rail pivot bases SEE FIGURE 12, to the rail pivot body SEE FIGURE 10 these edges can be attached to their respective edge heads , both tubular SEE FIGURE 13 and prism-shaped SEE FIGURE 14. This allows the range of designs of polyhedral structures to be expanded.

EDGE HEAD

It can be of two types: for a tubular edge or for a prism-shaped edge.

HEAD FOR TUBULAR EDGE

SEE FIG 13. In the figure, 13A is an internal side view, 13B is an external side view, 13C is a front view and 13D is a plan view. It is a cylinder (21), with a hollow part with an internal thread (26), with a closed end, crossed transversally through the center by a hole (27)

The cylinder is traversed transversally in its hollow body by 2 threaded holes located opposite each other, (22) for screws to pass through. At the end of the closed part it has a tab, (24), crossed with a smooth, unthreaded hole (23), the diameter of the threaded hole in the body of the rail pivot, (13). This tab has a rounded end edge, coinciding with the shape of the tab (12) of the body of the rail pivot.

The flange, in its inner part, has grooves (25), arranged radially, which coincide in size and frequency with the grooves on the body of the rail pivot (15).

HEAD FOR PRISM-SHAPED EDGE:

SEE FIG 14: In the figure, 14A is an internal side view, 14B is an external side view, 14C is a front view and 14D is a plan view.

It is a solid cylinder with a hole to introduce prism-shaped edges. The cylinder has 2 separate plates (28) at one of its ends, which form the hole, between which the aligned edge is placed. The plates have 2 transversal holes (29), through which screws are passed to anchor the edge to the head. You can also anchor the

edge with a screw that goes through the hole in the base of the cylinder (33)

The cylinder has a flange (31), traversed transversally by a smooth, unthreaded hole (30), the diameter of the threaded hole of the rail pivot (13). This tab has a rounded end edge, coinciding with the shape of the tab (12) of the body of the rail pivot.

The flange, in its inner part, has grooves (32), arranged radially, which coincide in size and frequency with the grooves on the flange of the body of the rail pivot (15).

The edge connection system through the union of discs for the assembly of polyhedral structures has an advantage of multi-angle connection, in reference to the greater range of edge connection angles offered by SEE FIGURE 15, due to the effect of the combination of turns of the elements that compose it: on the one hand, SEE FIGURE 15A, the rails of the large disk and the small disk allow the placement and displacement of the rail pivots through the 360° of their circumferences, to later be able to join them with the edge heads, when most other solutions on the market have fixed positions for the edges.

On the other hand, SEE FIGURE 15B, the edge head before being anchored to the rail pivot, has a turning angle of 180°, when the rest of the market solutions that have mobile heads allow angles with a maximum of 90°. This differential characteristic allows the assembly with the same edge connector of all frequencies of geodesic domes.

The coupling of the small disk, on one or both faces of the edge connector formed by joining two large symmetrical disks, and the edges that can contain it, allows the assembly of multiple designs of polyhedral structures and the possibility of combining and joining the designs of these, being a characteristic that differentiates it from the solutions of the competition.

In addition, the possibility of using the central hole of the large disc (5), either to insert the small disc SEE FIGURE 8 and SEE FIGURE 9, or to insert the body of a rail pivot, see FIG 10, to later join it to a head edge, either tubular, SEE FIGURE 13, or prism-shaped, SEE FIGURE 14, allow the union of geodesic domes, whether they are of the same size, SEE FIGURE 16, or different sizes, SEE FIGURE 17. It also allows the union of geodesic domes of the same or different sizes. frequency.

Another advantage of the system: the possibility of using the disks individually, both the large and the small disk, to anchor them to flat surfaces through the central hole and take advantage of the variable number of edges that can be connected to both disks to create multiple designs of structures polyhedral.

FIXING SCREW:

The rail pivot and the edge head, both tubular and prism-shaped, are joined by a clamping screw, (51) SEE FIG 28C, FIG 28D AND FIG 28F, SEE FIG 29C, FIG29D and FIG 29F, of equal length at least to the sum of the width of the flanges of the body of the rail pivot and of the flange of the edge head, whether tubular or prism-shaped. This screw threads into the threaded cross hole (13) in the flange of the rail pivot body.

EDGE

The length of the edges depends on the shape of the polyhedral structure and its size. In the case of geodesic domes, it depends on its radius and its frequency. Geodesic domes have stable proportions in the type of sizes of the edges that compose them: the higher the frequency, the greater the number of types of edge sizes.

The edge connector by joining two symmetrical discs offers the possibility of joining this edge with different characteristics and different materials, thanks to the two models of edge heads. This gives this edge connector a versatility that the competition's solutions do not have: those that can combine other types of edges can only do so with solid edges. The connector disc with head of tubular edges can connect solid edges and also smooth hollow edges, hollow with thread on the surface of their ends, solid or a combination of all.

The prism-shaped edge head connector disk can connect edges of the same thickness, but different widths. Also of various materials, using the appropriate screws.

With the Edge connection system by joining discs for the assembly of polyhedral structures, tubular edges with prism-shaped edges could even be combined in a polyhedral structure.

ANCHORING SQUARE:

To anchor the polyhedral structure to a surface, there is a square-shaped piece SEE FIG 18: 18A is the side view, 18B is the front view and 18C is the plan view. It has a vertical plate, (34); whose sides have the dimensions of the diameter of the large disc, attached perpendicularly to a horizontal rectangular plate (35), a threaded hole for connection with the disc (36), in the center of the vertical plate, with the same diameter as the central hole of the large disk (5), and of the central hole of the small disk (10); in the horizontal plate there are transversal holes (37) to anchor the structure to a surface. The upper half of the vertical plate is semicircular in shape, coinciding with the semicircle of the larger disk.

In summary, the advantages of using the edge connection system through the union of discs for the assembly of polyhedral structures are the following:

1. With a single connector model, a variable number of edges can be connected. This allows the possibility of more designs of polyhedral structures and in the case of geodesic domes, it saves having to manufacture a specific edge connector for the union of 4, 5 or 6 edges.

2. The combination of rotations of the elements that make up the system is much greater than the market solutions, SEE FIG 15 A and 15 B: on the one hand, the rail of the large disc and that of the small disc allow the placement of pivots of rail in its 360°, to join them later to edge heads; on the other hand, the rotation of the edge head is 180°. This allows the possibility of creating more designs of polyhedral structures and in the case of geodesic domes, the possibility of: using the same connector to mount domes of different frequencies, to join domes of the same or different sizes and to join domes of the same or different frequency

3. The two types of edge head allow the use of edges of different materials and diameters, in the case of tubular edges, and the use of different materials and thicknesses, in the case of using prism-shaped edges. The system even allows the combination in the same structure of tubular edges together with prism-shaped edges.

Preferred embodiment of the invention

The first thing we do is join the edge to its heads.

In the case of CORNER WITH LONGITUDINAL HOLLOW TUBE IN ALL ITS EXTENSION, SEE FIGURE 19, where, in all the letters, the upper drawing is a side view and the lower drawing is a top view section. (21) is the cylinder of the tubular head, (22) are the transversal holes of the cylinder of the tubular edge head; (23) is the hole for the head flange); (24) is the flange of the tubular edge head; (27) is the transversal hole of the cylinder of the head tubular edge; (38) is the edge with a longitudinal hollow tube in all its extension; (39) are short screws for tubular edge.

PROCESS:

FIGURE 19 A and FIGURE 19 B: The edge (38) is inserted to the bottom of the head cylinder (21).

FIGURE 19 C: to leave it anchored, insert the short screws (39) through the side holes (22) and tighten until the end.

FIGURE 19 D. The operation is repeated with the other end of the edge, ensuring that both heads are aligned.

In the case of CORNER WITH THREADED TUBE ON THE SURFACE OF THE ENDS: SEE FIGURE 20, where, in all the letters, the upper drawing is a side view and the lower drawing is a top view section. (21) is the cylinder of the tubular head, (22) is the transverse holes of the cylinder of the tubular edge head, (23) is the hole of the flange of the head; (24) is the flange of the tubular edge head; (27) is the transversal hole of the cylinder of the tubular edge; (40) is the edge with threaded tube on the surface of the ends.

PROCESS:

FIGURE 20 A and FIGURE 20 B: The threaded tube edge is introduced by turning on the surface of the ends (40) into the hole in the tubular edge, turning until it bottoms out. FIGURE 20 C: The operation is repeated with the other end of the edge.

In the case of SOLID PIPE CORNER: SEE FIGURE 21, where, in all the letters, the upper drawing is a side view and the lower drawing is a top view section. (21) is the cylinder of the tubular head, (22) is the transverse holes of the cylinder of the tubular edge head, (23) is the hole of the flange of the head; (24) is the flange of the head of the tubular edge, (27) is the transversal hole of the cylinder of the tubular edge, (41) is the solid tubular edge; (42) is a long screw for a solid part (43) is a short screw for a solid part.

PROCESS:

FIGURE 21 A and FIGURE 21 B: The solid tube edge (41) is inserted into the tubular edge cylinder (21), until it bottoms out.

FIGURE 21 C: To anchor the edge, a long screw for a solid part (42) is inserted through the cross hole of the cylinder of the tubular edge head (27) and through the cross holes of the cylinder of the tubular edge head (22). insert short screws for solid part (43). FIGURE 21 D: The operation is repeated with the other end of the edge, ensuring that the heads are aligned.

In the case of SOLID EDGES WITH LONGITUDINAL THREAD HOLE AT THE ENDS, SEE FIGURE 22, where in all letters, the upper drawing is a side view and the lower drawing is a top view section. (21) is the cylinder of the tubular head, (22) is the transverse holes of the cylinder of the tubular edge head, (23) is the hole of the flange of the head; (24) is the flange of the tubular edge head; (27) is the transversal hole of the tubular edge; (44) is the solid edge with a longitudinal thread hole at the ends; (42) is a long screw for a solid part (43) is a short screw for a solid part, (59) is the longitudinal threaded hole of the solid edge

PROCESS:

FIGURE 22 A and FIGURE 22 B: The solid tube edge with longitudinal thread hole at the ends (44) is introduced into the tubular edge cylinder (21), until it bottoms out. FIGURE 22 C: To anchor the edge, a long screw for a solid part (42) is inserted through the transversal hole of the tubular edge head (27), which is also inserted through the longitudinal threaded hole of the solid edge (59) and Short screws for solid part (43) are inserted through the transversal holes of the tubular edge head cylinder (22).

FIGURE 22 D: The operation is repeated with the other end of the edge, ensuring that the heads are aligned

For PRISM-SHAPED EDGES, SEE FIGURE 23 where in all letters, the upper drawing is a side view and the lower drawing is a top view section. (28) are the 2 head plates); (29) are the transverse holes of the plates; (31) is the flange of the prism-shaped edge head; (33) is the transverse hole at the base of the cylinder; (45) is the prism-shaped edge; (46) is a long screw for a prism-shaped edge; (47) is a short screw for a prism-shaped edge.

PROCESS:

FIGURE 23 A and 23 B. The prism-shaped edge (45) is inserted between the head plates (28), all the way down, so that the prism-shaped edge is centered with the plates. FIGURE 23 C In order for the edge to be anchored to the head, a long screw for a prism-shaped edge (46) is inserted through the transverse hole of the head (33) and short screws for the transverse holes of the plates (29) are inserted. prism-shaped edge (47) FIGURE 23 D. The operation is repeated with the other end of the edge, ensuring that the heads are aligned

The edges are separated by size, so that they are organized.

Next, the edge connector is assembled, and the rail pivot bases are placed in the desired position SEE FIGURE 24. Where (1) is the body of the large disc; (3) is the large disk rail; (4) are the grooves of the large disc; (16) is a screw arranged perpendicular to the plate of the pivot base of the rail for joining discs; (17) is the plate of the pivot base of the rail for joining discs; (48) is the disc union screw. (49) is the disc union screw nut.

PROCESS:

FIGURE 24A: The disc union screw (48) is passed through the central hole of the large disc (5).

FIGURE 24B: The rail pivot bases are placed in the desired position; (16) is the rail base plate for joining symmetrical discs; and (17) is the screw of the rail base.

FIGURE 24C: The other large disc is passed in a symmetrical position through the disc union screw (48) and is positioned so that the grooves of both discs fit together

and anchor.

FIGURE 24D: Finally, the nut is passed through the screw (49) and tightened to the bottom, so that the two symmetrical discs are joined and the pivot bases are anchored.

The next step is to attach the base of the disc attachment rail pivot to the body of the rail pivot. SEE FIGURE 25, where (11) is the cylinder of the rail pivot body; (12) is the flange of the rail pivot; (13) is the cross hole of the rail flange; (16) is the screw of the pivot base of the rail for joining discs; and (17) is the

rail pivot base plate for disc attachment.

PROCESS:

Figures 25A to 25F show how the screw at the base of the rail pivot (16) is inserted into the longitudinally threaded hole of the body of the rail pivot (14), by turning it all the way, so that the tab is arranged in such a way that, when joining the edge head, it rotates transversally to the edge connector.

FIGURE 26 is a section of the side view of the joint assembly of the two symmetrical discs, with two rail pivots installed. Where (1) is the body of the large disk; (11) is the cylinder of the body of the rail pivot; (12) is the flange of the rail pivot body; (13) is the transverse hole of the flange of the body of the rail pivot; (15) are the splines of the flange of the body of the rail pivot; (16) is the screw of the pivot base of the rail for joining discs; (17) is the plate of the pivot base of the rail for joining discs; (48) is the disc union screw; (49) is the is the disc union screw nut.

FIGURE 27 shows examples of edge connectors by joining large disks with several anchored pivots. All letters show plan views. (1) is the body of the large disk; (5) is the smooth central hole of the large disk; (11) is the cylinder of the body of the rail pivot; (12) is the flange of the rail pivot body.

Figure 27 A shows an edge connector formed by 2 large symmetrical discs with 2 anchored rail pivots; Figure 27 B shows an edge connector formed by 2 large symmetrical discs with 4 anchored rail pivots; Figure 27 C shows an edge connector consisting of 2 large symmetrical discs with 6 anchored rail pivots.

This demonstrates that with a single edge connector model a variable number of edges can be connected and, in the case of mounting geodesic domes, the need to manufacture a specific 4-edge, 5-edge and 6-edge connector is avoided. edges, with the manufacturing costs that this entails.

When the edge connectors are anchored with the rail pivots, the rail pivot is joined to the edge head, both tubular edge and prism-shaped edge.

Figure 28 describes the joining process of the tubular edge head with the rail pivot. In this figure (11) it is the cylinder of the rail pivot body; (12) is the flange of the rail pivot body; (13) is the transversal hole of the flange of the body of the rail pivot; (15) are the splines of the rail pivot body flange; (16) is the screw of the pivot base of the rail for the union of discs see; (21) is the cylinder of the head of the tubular edge, (23) is the transversal hole of the flange of the head of the tubular edge; (24) is the flange of the head for tubular edge; (38) is the edge with a longitudinal hollow tube in all its extension; (39) are the cross screws of the edge head cylinder; (51) is the fastening screw that joins the head with the rail pivot through the transversal hole of both pieces.

PROCESS:

FIGURE 28 A and 28 B shows how the head of one end of the tubular edge is aligned with the rail pivot, so that the transversal holes of both pieces (13) and (23) coincide. In both figures, the drawing on the right is a side view and the one on the left is a front view. FIGURE 28C shows how a union screw (51) is passed through the transversal holes of the body of the rail pivot (13) and of the edge head (23). The screw is not tightened completely, so that the edge head has rotation play. This figure is a front view. FIGURE 28D shows the possibilities of turning the edge. In both figures, the drawing on the right is a side view and the one on the left is a front view.

FIGURE 28E graphically shows the potential range of rotation of the edge on the rail pivot. This figure is side view.

FIGURE 28F when the angle of rotation of the edge head and pivot joint is decided, the screw (51) is fully tightened. This causes the head flange (25) and rail pivot body flange (15) splines to anchor, so that the assembly can no longer move. In both figures, the drawing on the right is a side view and the one on the left is a front view.

Figure 29 describes the joining process of the prism-shaped edge head with the rail pivot. In this figure (11) it is the cylinder of the rail pivot body; (12) is the flange of the rail pivot body; (13) is the transverse hole of the rail pivot body flange; (15) are the splines on the inside of the rail pivot body flange; (28) are the 2 plates that the cylinder of the prism-shaped edge head has at one of its ends, between which the edge is placed; (30) is the unthreaded hole in the head flange, the diameter of the threaded hole in the rail pivot (13); (31) is the flange of the prism edge head; (45) is the prism-shaped edge; (47) is the short screw for prism-shaped edge; (51) is the screw that joins the edge head with the rail pivot through the transversal hole of both pieces.

PROCESS:

FIGURE 29A and 29B shows how the head of one end of the prism-shaped edge is aligned with the rail pivot, so that the transversal holes of both pieces (13) and (30) coincide. In both figures, the drawing on the right is a side view and the one on the left is a front view.

FIGURE 29C shows how a union screw (51) is passed through the rail pivot (13) and edge head (30) cross holes. The screw is not tightened completely, so that the edge head has rotation play. This figure is a front view.

FIGURE 29D shows the possibilities of turning the edge. In both figures, the drawing on the right is a side view and the one on the left is a front view.

FIGURE 29E graphically shows the potential range of rotation of the edge on the rail pivot. This figure is side view.

FIGURE 29F when deciding the angle of the joint between the edge head and the rail pivot, the screw (51) is fully tightened. This causes the splines on the head flange (32) and on the rail pivot tab (15) are anchored so that the assembly can no longer be moved. In this figure, the drawing on the right is a side view and the one on the left is a front view.

Figure 30 shows plan views of several examples of edge connectors with several prism-shaped edges attached to them. In these figures: (1) is the external body of the large disc see; (5) is the smooth central hole of the large disc see; (11) is the cylinder of the rail pivot body; (12) is the flange of the rail pivot body; (28) are the 2 edge-shaped head plates; (31) is the flange of the prism-shaped edge head; (45) is the prism-shaped edge, (51) is the rail pivot union screw and edge head

In FIGURE 30A a connector with 2 joined edges is shown. In FIGURE 30B a connector with 4 joined edges is shown. FIGURE 30C shows a connector with 6 joined edges.

Figure 31 shows a plan view of the union of several edge connectors with each other by means of prism-shaped edges. Through this process, the desired polyhedral structure is shaped. This shape is achieved by anchoring the necessary number of edges to the connectors, which can be variable, and by the angle that the edges take in relation to the connector. The process is identical using tubular edges. In this figure (1) is the external body of the large disc to see, (5) is the smooth central hole of the large disc to see; (11) is the cylinder of the rail pivot body; (12) is the flange of the rail pivot body; (28) are the 2 head plates for prism-shaped edges; (31) is the flange of the prism-shaped edge head; (45) is the prism-shaped edge; (51) is the screw that joins the edge head with the rail pivot through the transversal hole of both pieces.

Figure 32 shows the anchoring process of a small disk on the face of an edge connector formed by two joined large disks, arranged symmetrically. Subsequently, in the smaller disc, the pivot body is attached to the pivot base for the disc used individually. Through this process, more edges can be attached to a connector and the possibilities of assembling polyhedral structures are increased.

In this figure 32, (1) is the outer body of the large disk, (5) is the smooth central hole. of the large disc; (7) is the external body of the small disk; (10) is the central cross hole of the small disk; (11) is the cylinder of the rail pivot body; (12) is the flange of the rail pivot body; (13) is the transverse hole of the flange of the rail pivot body; (15) are the grooves on the inside of the rail pivot body flange, (16) is the rail pivot base screw for disc attachment see, (17) is the rail pivot base plate rail for disc attachment, (18) is the threaded screw arranged perpendicular to the body of the rail pivot base for individual disc use, (19) is the body of the rail pivot base for individual disc use, ; (20) is the curved flange in the shape of the rail of both the large and small discs; (52) is the small disc union screw with the connector formed by two large discs; (53) is the union screw nut.

PROCESS:

Figure 32A: First, the tabs (20) of the individual disc use rail pivot bases are positioned in the desired position on the small disc rail. In this figure, the drawing on the left is a cross-sectional side view and the drawing on the right is a plan view. This figure shows the anchoring of 2 rail pivot bases.

Figure 32B: Then, the hole of the edge connector (5) is aligned with the hole of the small disk (10), so that they coincide. In this figure, a cross-sectional side view is shown.

Figure 32C: A union screw (52) is passed through the holes (5) and (10) of the discs and a nut (53) is screwed on. It is not fully tightened until the bases (17) and ( 20) of rail pivots in the desired position. When they are, it is tightened to the bottom. In this figure, a cross-sectional side view is shown.

Figure 32 D to 32 G The body of the rail pivot is attached to the pivot base for the disc used individually. To do this, the pivot body is inserted through its longitudinal hole in its base (14), through the pivot base screw (18), turning the body until it comes to a stop with the smaller disc. In these figures, a side view is shown.

Figure 32 H: Shows a side sectional view of the connector assembly together with a small disc attached to one side of the connector, with the discs in section, and both with anchored rail pivots. In this figure, a cross-sectional side view is shown.

Figure 32 I: Shows plan view of an edge connector with 6 anchored rail pivots and an attached minor disc, with 2 anchored rail pivots

Figure 33 shows, in several lateral cross-sectional views, how the edge connector is attached to an anchoring bracket and how the assembly is anchored to a surface. In this figure (1) is the outer body of the large disc see , (11) is the cylinder of the rail pivot body; (13) is the transverse hole of the flange of the rail pivot body; (15) are the grooves on the inside of the rail pivot body flange, (16) is the rail pivot base screw for disc attachment see, (17) is the rail pivot base plate rail for joining discs, (34) is the vertical plate of the anchoring bracket, (35) is the horizontal plate of the anchoring bracket; (36) is the transversal hole of the vertical plate of the anchor bracket; (37) are the transversal holes of the horizontal plate of the anchor bracket; (53) is the disc union screw nut; (54) is the connecting screw of the edge connector with the anchoring bracket; (55) are the anchor bolts to a surface; (56) is the surface where the connector and bracket assembly is anchored.

PROCESS:

FIGURE 33 A: The edge connector formed by 2 large discs arranged symmetrically is pierced through its central hole by a screw (54) that holds the discs together. This screw is inserted through the transversal hole (36) of the vertical plate (34) of the anchoring bracket.

FIGURE 33B: the bracket and connector assembly is anchored by means of a nut (53) that is passed through the end of the screw (54). It is used to relocate the connector rail pivots and the nut is tightened to fix the connector and bracket assembly.

FIGURE 33C: Finally, the assembly is anchored to the surface (56) with some screws (55) that are passed through the holes (37) of the horizontal plate (35) of the anchoring bracket.

Figure 34 shows, in various side cross-sectional views, the use of a disc individually to anchor edges. In this case, the use with a small disk is shown, but the same mode would apply with the large disk. The only difference is that the large disc allows for more rail pivots to be attached to edge heads.

In this figure (7) it is the external body of the small disk; (9) is the rail of the small disk; (10) is the smooth transverse center hole of the small disk; (11) is the cylinder of the rail pivot body; (12) is the flange of the body of the rail pivot; (13) is the transverse hole of the flange of the rail pivot body; (15) are the splines on the inside of the flange of the body of the rail pivot; (18) is the threaded screw arranged perpendicular to the body of the base of rail pivot for individual disc use, (19) is the body of the base of the rail pivot for individual disc use; (20), is the rail-shaped curved flange of the rail pivot base for individual disc use; (57) is the surface where the disk is anchored, (58) is the appropriate screw for each surface.

PROCESS:

FIGURE 34 A: First, the tabs (20) of the individual use rail pivot bases are placed in the desired positions on the disc rail (9), in this case the small disc. This figure is a side cross-sectional view.

FIGURE 34 B: The assembly is placed on a surface. Through the central hole of the disc, in this case the small one (10) a suitable screw/nail is passed to the surface. This figure is a side cross-sectional view.

FIGURE 34 C: The pivot bases are adjusted to the desired positions and the screw/nail is tightened to anchor the disc to the surface. This figure is a side cross-sectional view.

FIGURES 34D: Shows the small disc anchored to the surface and with the rail pivot bodies attached to the disc rail pivot base used individually. This joining process appears in Figures 32D to 32G and is explained on page 17, lines 14 to 18. This figure is a side view and the small disc is shown in cross section.

The process of joining the rail pivot to the tubular edge head is shown in figure 28 and is described from line 7 on page 14 to line 24 on the same page.

The process of joining the rail pivot to the prism-shaped edge head is shown in figure 29 and is described from line 3 on page 15 to line 20 on page 15.

Claims (6)

1. EDGES CONNECTION SYSTEM BY JOINING DISCS FOR THE ASSEMBLY OF POLYHEDRAL STRUCTURES, characterized by being composed of several solid discs, of 1 or 2 sizes and by rail pivots attached to edges with their respective heads at both ends of these ; the largest disc has, along the outside of the circumference of the internal face of its body (2), an L-shaped rail (3); Said larger disk has a smooth hole (5) in the center that crosses it transversally; the union of two larger discs symmetrically on their internal face gives rise to the EDGE CONNECTOR, said edge connector has a variable number of rail pivots arranged longitudinally and anchored along the length of the rail in the shape of an inverted T ( 6) of said connector, this rail is the result of the union of the L-shaped rails of both larger discs. The rail pivots consist of a body and a base: the rail pivot bases for joining discs symmetrically (17) are inserted into the desired places on the larger disc rail (3), said bases have the same dimensions in width and height than the inverted T-shaped rail (6) of the edge connector. By joining two larger discs on their internal face and anchoring them by means of a screw that goes through the central transversal hole (5) of both discs and nut, the rail pivot bases are fixed. At that moment, the rail pivot body and rail pivot base are joined by introducing the pivot base screw (16) through a longitudinal hole with thread (14) of the pivot body, by turning it, the body being anchored longitudinally to the edge connector. The body of the rail pivot has a flange (12), with grooves in its internal part arranged radially (15) and a threaded hole that crosses through its center transversally (13). 2. EDGE CONNECTION SYSTEM BY JOINING DISCS FOR ASSEMBLY OF POLYHEDRAL STRUCTURES according to Claim 1, whose EDGE CONNECTOR rail pivots are characterized by being attached to heads for TUBULAR EDGE, by their respective tabs. The heads are located at both ends of the corresponding edge. The tubular edge head has a flange (24), with radially arranged grooves on its internal part (25), with the same frequency and dimensions as those of the flange of the rail pivot body (15) and a smooth hole that runs through it. through its center transversally (23). This hole is the same diameter as the hole in the rail pivot tab (13). The flange of the tubular edge head (24), before being attached and anchored to the flange of the rail pivot body (12), by the faces of both that have the grooves, by means of a screw (51), has a turn of 180 degrees transverse to the center of the EDGE CONNECTOR. 3. EDGE CONNECTION SYSTEM BY JOINING DISCS FOR ASSEMBLY OF POLYHEDRAL STRUCTURES according to Claim 1, whose larger disc rail pivots are characterized by being attached to PRISM-SHAPED edge heads, by their respective tabs. The heads are located at both ends of the corresponding edge. The prism-shaped edge head has a flange (31), with radially arranged grooves on its internal part (32), with the same frequency and dimensions as those of the flange of the rail pivot body (12), and a hole smooth that passes through its center transversally (30). This hole is the same diameter as the hole in the rail pivot tab (13). The flange of the prism-shaped edge head (31) before being attached and anchored to the flange of the rail pivot body (12), on the faces of both that have the grooves, by means of a screw (51), has a 180 degree turn transversely with respect to the EDGE CONNECTOR center. 4. EDGE CONNECTION SYSTEM BY JOINING DISCS FOR ASSEMBLY OF POLYHEDRAL STRUCTURES according to Claim 1, characterized by having coupled, on one or both sides of the edge connector, ONE 5 SOLID DISC, WITH SMALLER DIAMETER than the other system disk model; this smaller disc has, along the outside of the circumference of the internal face of its body (8), an L-shaped rail (9); Said smaller disc has a smooth hole (10) in the center that crosses it transversely, with the diameter of the transverse hole of the larger disc (5). The smaller disc has a variable number of rail pivot bases placed along its rail, (9) arranged perpendicularly. These rail pivot bases, specific for individual use of the smaller disc, are inserted into the rail (9) of the smaller disc, as said bases have a tab (20) with the same dimensions in width and height as the rail (9). . The smaller disk is joined by its internal face (8) to one or both faces of the edge connector, making the transverse hole of the smaller disk (10) coincide with the transverse hole of the edge connector (5), so that the set is crossed by a screw (52). When this screw is tightened with a nut, the whole assembly is anchored and the bases of the rail pivots of the minor disk are fixed. The rail pivot base is then attached to the rail pivot body, which is the same as that of the larger disc: by turning the pivot body, the single use rail pivot base screw (18) is inserted. ) through the lower hole (14) of the body of the rail pivot. 5. EDGE CONNECTION SYSTEM BY JOINING DISCS FOR THE ASSEMBLY OF POLYHEDRAL STRUCTURES according to Claims Two and Four, where the smaller disc is characterized by having the flanges of the rail pivots (12) joined on the face where the grooves are located. (15) with the flanges of the heads for TUBULAR EDGE (24) of one of the ends of the edge by the face of the edge head flange where the grooves (25) are found, by means of a fastening screw (51) that it passes through the flange hole of the rail pivot body (13) and the flange hole of the tubular edge head (23) and has the same diameter as both holes. The rail pivot body is fixed perpendicularly to the smaller disc, so that the rotation of the flange of the TUBULAR RIDDLE head (24) on the rail pivot body (11), by its flange (12), before being anchored , is 180 degrees transverse to the center of said disk 6. EDGE CONNECTION SYSTEM BY JOINING DISCS FOR THE ASSEMBLY OF POLYHEDRAL STRUCTURES according to Claims 3 and 4, where the smaller disc is characterized by having the flanges of the rail pivots (12) joined on the face where the grooves are located. (15) with the flanges of the heads for PRISM-SHAPED CORNER (31) from one of the ends of the edge by the side of the flange of the edge head where the grooves (32) are found, by means of a fastening screw ( 51) ), which passes through the flange hole of the rail pivot body (13) and the flange hole of the prism-shaped edge head (30) and has the same diameter as both holes. The rail pivot body is fixed perpendicularly to the smaller disc, so that the rotation of the flange of the PRISM-SHAPED EDGE head (31) on the rail pivot body (11), by its flange (12), before to be anchored, is 180 degrees transversally with respect to the center of said disk