SK6537Y1 - Coupling with insertable distance element - Google Patents

Abstract

Coupling with an embeddable distance element (3) as part of the structure element suitable for creating a permanent formwork for the construction of energy efficient houses with a massive construction, according to a technical solution consists of wall brick elements (2) with a reinforcing ribbing (5), with a wide supporting base (4) and embeddable distance element (3) for keeping of wall bricks (20) in a parallel position. On inner vertical edge of wall brick elements (2) is formed a groove (6) with a edge (7). The distance element (3) comprises reinforcing ribbing (12), reinforcement of the body (11) and sections (19) and on vertical edges of a holding frame is equipped with reinforcing ribbing (12) and tongue (13). Tongue (13) is on one or more sections fitted with safety flexible clips (14), with a front (15) and a stop (16) at their ends for stopping and fix the clip (14) on the wall of the groove (6). In the edge (7) of the groove (6) of wall brick element (2) are created several openings (9) for inserting and fixing of clip (14), and thus for mutual fixation of the inserted distance element (3) and wall brick elements (2).

Description

Technical field

The technical solution relates to a coupling with an insertable spacer part usable for the construction of energy-efficient houses with a massive construction.

BACKGROUND OF THE INVENTION

Pre-fabricated and hollow or polystyrene moldings have been present in environmentally-friendly and cost-effective construction technologies since the 1980s, which are easier to transport than conventional materials and, on the other hand, allow a faster, cleaner and more accurate construction process. This results in a safer building with better thermal insulation and sound insulation properties.

Hungarian utility model no. HU 3317 discloses double-wall polystyrene building elements with vertical signaling ribs made with interconnections which, due to their calibrated dimensions and the upper and lower toothed surfaces, are well bondable as lego. These elements can be used to create formwork without gaps, which according to statics requirements can be supplemented with vertical or horizontal iron reinforcement and poured with concrete, creating the wall of the desired strength, and immediately with double-sided insulation; for its smooth surface it is possible to apply plaster economically; for signaling ladders, it is easy to mount on such a wall. In the case of this utility model, the solid connections are made of plastic or metal when the polystyrene sheets are poured with concrete; in other known solutions, the interconnections and side walls are made of the same material in one casting.

Further refinement of such building elements, which can also serve as permanent formwork, would be very important, since the thickness of the concrete layer and hence the thickness of the building, predetermined by the length of the interconnection, limits the design possibilities and limits the height of buildings. At the same time, most of the volume of the prefabricated elements - more than half according to the thickness of the polystyrene sheets - takes up the air gap created by the interconnection, so the packaging and transport of the elements is largely air transport. Transporting loads with a large volume but too low a weight is a problem that largely limits the range of structures that could be supplied from a given production site.

There is a solution in which the side wall prefabricates are connected in a vertical position by means of rod spacers inserted into the upper and lower surfaces by disc holders with parallel side outer wall elements and thus form a permanent formwork. According to experience, the overall strength of such formwork is lower, so on the one hand the concrete core of the wall cannot be arbitrarily thick, on the other hand it is recommended to concret after assembly of several rows, so assembly and concreting cannot be divided over time.

The change in production was also verified in such a way that the interconnection was installed at the site of assembly into edge grooves that had been preformed on the inner wall of the building element, but due to the low edge resistance, strength problems occurred and assembly was also slowed.

The object of the invention is to provide such a connector which can also be used as a permanent shuttering, while maintaining the known advantages of polystyrene wall elements and technology, allowing for greater thickness variability between peripheral and partition walls, as well as volume savings and cost effective assembly.

The essence of the technical solution

This is accomplished by a coupling with an insertable spacer as part of a structural element suitable for creating permanent formwork and for the construction of energy-efficient houses with a massive construction according to a technical solution consisting of a spacer and stiffening ribs with reinforcing ribs and a wide supporting base. In the manufacture, the wall panels are molded into the inside of the polystyrene wall panels connected on the upper and lower side by a toothed lock, and equipped with signaling ribs on the outside of the inner or outer wall to indicate the position of the connectors in the wall.

The wall panels, comprising a wide support base and reinforcing ribs, are provided on their inner vertical edge with a groove for inserting the spacer. The spacer, including a reinforcing rib, a reinforced body and die cuts, is provided with a perch on the vertical edges of the holding rib reinforcing frame. The groove of the wall panels together with the spacer tongue forms a connecting element when inserting the spacer panel into the wall panels.

The spacer panel tongue on one or more sections is provided with resilient clip clips, a face, and a stop at its ends to stop and fix the clip to the groove wall of the stem panel. The clip in the equilibrium state protrudes from the profile of the tongue edge and tapers in a curved manner. Due to the force from the direction

SK 6537 Υ1 the bound end is a clip capable of flexible movement directed perpendicularly to the edge of the tongue. A plurality of holes are provided in the groove edge of the stem panel for insertion and fixation of the clip, and thus for the interlocking of the intermediate spacer and the stem panels.

It is considered advantageous if the groove with the edge of the panel and the tongue of the spacer are in the form of "T".

It is further preferred that the alignment of the couplings in the wall plates is uniform or cyclic within the specified modules.

The clutch spacer fits into the pre-woven wall elements inside the wall elements - external and internal. By means of insertable spacers, the two wall joints can be joined together to form a unit as a fixed unit.

The advantage of the present technical solution and at the same time the difference from the previous technical solutions is that the coupling (and hence the final building element consisting of the stalks with stalks and spacers) is assembled directly on site by stacking the stalks and spacers that are produced and transported to building separately. The previous solutions were based on the fact that the construction elements consisting of the wall joints with the couplings were manufactured as one unit, ie the coupling was fixed in the production of the construction element. The present solution has achieved that new building elements with a specified wall thickness and stiffness are assembled directly on site by virtually a few simple movements of polystyrene stens with interwoven steners by inserting spacers. At the same time, this significantly reduces the cost of transporting parts for construction.

The width of the spacer of the coupling determines the distance between the walls and may vary in different embodiments of the invention.

A great advantage of the building element is that it is provided on the outside of the wall with vertical signaling ribs to indicate the position of the couplings.

In some cases, the outer and inner polystyrene wall is of the same thickness, in other cases of different thickness.

The building element wallboards are generally plates, but there may also be wall plates with an angle break.

BRIEF DESCRIPTION OF THE DRAWINGS

The essence of the technical solution will be explained in more detail in the attached figures, where:

Fig. 1 is a cross-sectional view of a connector of a building element during insertion of a spacer, a front view.

Fig. 2 shows a front view of one of the possible preferred embodiments of the building element.

Fig. 3 is a cross-sectional view of the coupling in an exploded state prior to mounting a spacer with two stem members, a front view.

Fig. 4 is an axonometric view of the edge of the spacer of FIG. 3 with "T" spring and spring clips.

Fig. 5 is an axonometric view of the " T " groove of the wall piece with the holes for engaging the resilient securing clips.

Fig. 6 shows one of the possible embodiments of the building element assembly, seen from above.

Fig. 7 is a cross-sectional view of a detail of an interlocked wall panel with a base and a " T " groove.

Fig. 8 is a top view of one of the possible embodiments of a wallet with nested wall panels.

Fig. 9 shows another possible embodiment of a wallet with interlocked wall panels in pairs in a module, seen from above.

Fig. 10 shows another possible embodiment of the building element assembly, seen from above.

EXAMPLES

In FIG. 1 shows a cross-sectional view of one of the possible preferred embodiments of a connector 1 of a building element with wide support base 4 with a wide support 4 during insertion of the spacer 3. The wide support support base member 2 is woven into the inside of the wall 20 equipped with tooth locks 21 on the top and bottom of the stalks 20.

In FIG. 2 shows one of the possible preferred embodiments of the technical element of the building element formed by the stems 20 with the stent elements 2 interposed and the insertable spacer 3.

Fig. 3 shows one possible embodiment of the present embodiment of the coupling 1 in a disassembled front view in sectional view, wherein the wall elements 2 with reinforcing ribs 5 are provided with a wide support base 4 and on their inner vertical edge with a groove 6 with edge 7 for inserting a spacer 3 In the manufacture, the wall panels 2 are incorporated vertically into the inside of the wall panels 20. The spacer 3 is

SK 6537 Υ1 equipped with perforated body with reinforcement 11 with cuts 19, reinforcing ribs 12, and on vertical edges of the holding frame reinforcing ribs 12 with a tongue 13. The groove 6 of the wall panels 2 together with the tongue 13 of the spacer 3 forms a connecting element when inserting the spacer 3 wall elements 2.

In the preferred embodiment of the spacer 3, the body with body reinforcement 11 consists of three parallel reinforcement portions, two of which are laterally provided with punches 19 to retain the body reinforcement 11 of the spacer 3.

According to FIG. 3 it is clear that the assembly of the coupling 1 is possible in that the "T" tongue 13 of the spacer 3 is inserted in parallel in the "T" grooves 6 on the side edges of the wall panels 2. If they fit tightly or if the wall panel 2 As the receiving element is closed from below, the spacer 3 is fixed in the groove 6 of the wall panels 2 without further stabilizing element. In FIG. 4 and 5, a preferred embodiment of the structural fixation of the spacer 3 and the wall panels 2 during their folding is explained.

In FIG. 4 is an axonometric view of the spacer 3 of FIG. 3 is provided with a perforated body with reinforcing ribs 11 reinforcing the ribs 12, and with the vertical edges 12 of the reinforcing ribs 12 on the vertical edges. In the figure, the tongue 13 of the spacer 3 in the example is provided at both end portions and the stop 16 at the end. The clips 14 are free end projections, in the state of equilibrium they protrude against the profile of the edge of the tongue 13 and taper arcuate. Due to the force from the direction of the bound end, the clips 14 are capable of flexibly moving perpendicular to the direction of movement of the lip edge 13.

In FIG. 5 shows an axonometric view of the wall piece 2 with reinforcing ribs 5 by a wide support base 4 of the elastic securing clips. In the figure, we can see that in the edge 7 of the "T" groove 6 of the wall piece 2, an opening 9 is formed for inserting and fixing the securing spring clip 14 of FIG. 4, and hence for the interlocking of the spacer 3 and the stalks 2.

FIG. 4 and 5, the spring clip 14 and its shape facilitate the insertion of the "T" tongue 13 into the "T" groove 6. By moving the "T" tongue 13 against the clip 14 during insertion into the "T" groove 6, the clip 14 is pressed down compared to the state of equilibrium and the "T" tongue 13 is inserted into the "T" groove 6. In the event that it reaches the opening 9, the clip 14 is lifted and if necessary the clip 14 can be moved further and due to force in the direction of the closed end that forms the stop 16, the clip 14 drops again. Upon movement in the opposite direction, the clip 14 at the opening 9 is raised, and the impact portion of the wall of the groove 6 prevents further outward movement.

During assembly, the slight taper of the face 15 of the "T" tongue 13 facilitates the insertion of the spacer 3 into the wall panels 2 and the insertion into the "T" groove 6 with the edge 7 and the bore 9. The movement stops when the stop 16 of the tongue 13 reaches the end "T". In this case, one or more clips 14 of the opening 9 on the wall "T" of the groove 6, force the force to cease, the clip 14 moves towards the equilibrium state, thereby raising and fitting precisely into the opening 9, preventing By further clipping the clip 14 into the opening 9, the spacer 3 is fixed and prevented from moving further.

Thus, the "T" groove 6 with the edge 7, the "T" tongue 13, the resilient locking clip 14 and the opening 9 form a strong bond, thereby forming a stiff and load-resistant coupling 1 from the wall elements 2 and the spacer 3. .

The difference with the prior art is that in the present invention, the wall part 2 with a wide support base 4 is incorporated vertically into the inside of the wall 20 during production, so it is not necessary to integrate the entire coupling 1 into the wall 20 in advance. is produced and transported to the construction site separately and the parts are assembled and fixed only at the construction site. The saving of transport costs is considerable, in the same volume it is possible to transport a significantly larger amount of material. At the construction site, by placing and fixing the spacer 3 into the wall panels 2, we obtain a building material with a strength similar to traditional formwork blocks.

Fig. 6 illustrates one possible embodiment of a building element assembly, seen from above. Stands 2 are wedged into the two parallel assemblies 20 and spacers 3 are inserted into the stems 2 to form a rigid, stable building element. In this case, the thickness of the wall 20 is the same and the connectors J are evenly distributed in the module. On the outside of one of the stalks 20 there are vertical shallow signal ribs 23 on the surface, indicating the location of the connectors 1 in the building element.

Fig. 7 shows a detail of a cross-section of the wall piece 2, with the base 4, with reinforcing ribs 5 and a "T" groove 6 vertically inserted into a wall 20 equipped with a tooth lock 21 on the top and bottom of the walls 20 and a signal rib 23. 6 serves as a receiving element for the spacer 3.

Fig. 8 shows an exemplary embodiment with a thicker wall 20 with the placement of the wall panels 2 which are incorporated into the wall panel 20, wherein six wall panels 2 are equally spaced over the entire length of the wall panel 20.

Fig. 9 illustrates an exemplary embodiment wherein the stalk panels 2 in the stalks 20 are not positioned equally

This solution is useful when the steel reinforcement has to be reinforced by double bonding according to the static requirements.

FIG. 10 when compared to the embodiment of FIG. 6, the wall plates 20 are of different thicknesses, and their desired spacing is greater, therefore longer couplings 1 are incorporated to form a thicker concrete core, thereby creating a wall capable of sustaining a greater load.

Accordingly, the variable connection coupling 1 with the insertable spacer 3 provides greater design freedom and design in comparison to the prior art, since the elements of the lost shuttering are assembled in place from stems 20 with built-in stems 2 of different thicknesses depending on function, and spacers of 3 - prefabricated elements in required number and width. Also, due to the manner of binding between the joined elements, the formwork will have the necessary strength.

Therefore, the technical solution is an efficient and cost-effective solution.

Industrial usability

The technical solution can be used in the construction industry in the construction of energy-efficient houses with a massive construction.

Claims (6)

PROTECTION REQUIREMENTS A coupling with an insertable spacer as part of a building element suitable for creating permanent formwork and for building energy-efficient houses with a massive construction, consisting of polystyrene stems (20) with a joint lock (21) with teeth on the top and bottom of the stems (20 ) and signaling ribs (23), characterized in that it consists of stalk elements (2) with reinforcing ribs (5) and a wide support base (4), molded into the inside of the stems (20); further comprising an insertable spacer (3) for keeping the stems (20) in parallel. Insertable spacer connector according to claim 1, characterized in that a groove (6) with an edge (7) for inserting the spacer (3) comprising a reinforcing rib (12) is formed on the inner vertical edge of the wall panels (2). , a body reinforcement (11) and cut-outs (19), and provided with a tongue (13) on the vertical edges of the ribbing support frame (12), wherein the groove (6) of the wall panels (2) together with the tongue (13) of the spacer (3) form a connecting element when inserting the spacer (3) into the wall panels (2). Insertable spacer coupling according to claim 1 and 2, characterized in that the tongue (13) is provided on one or more sections with safety spring clips (14), a face (15) and a stop (16) at its ends and fixing the clip (14) to the wall of the groove (6) of the wall piece (2), wherein the clip (14), in equilibrium state, protrudes from the edge profile of the tongue (13) and tapered, 2) a plurality of openings (9) are provided for inserting and fixing the clip (14) and thereby fixing the spacer (3) and the stalks (2) together. Insertable spacer coupling according to claims 1 to 3, characterized in that the groove (6) with the edge (7) of the wall piece (2) and the tongue (13) of the spacer piece (3) are in the form of HERE 5> 1 · Insertable spacer coupling according to claim 1, characterized in that the alignment of the couplings (1) in the stems (20) is uniform. Insertable spacer coupling according to claim 1, characterized in that the alignment of the couplings (2) in the stems (20) is cyclic in the determined modules.