CZ290305B6 - Spacer - Google Patents

Abstract

A spacer for building purposes functioning as anchoring and connecting member for identical or different building materials, consists of at least one tubular element (1) made in the form of a roll, with eyes or perforations all over its surface, filled with a filling material (6) inside as well as outside the tubular element (1) inclusive of the eyes or perforations. In preferred modification the filling material a foamed plastic, preferably based on polyurethane, and for some purposes there are preferred even usual building materials either individually or in combination of plaster, cement, sand, lime, pearlite, adhesives and binding agents. Advantageously, the tubular elements (1) of different diameters are inserted one in another. The tubular element (1) can be made of metal mesh or perforated sheet with holes or notches, but also of solid perforated plastic. Inside the tubular element (1) and in the filing material (6) there is inserted at one or both ends thereof a fastening element (12).

Description

Spacer

Technical field

The invention relates to a spacer for building purposes.

BACKGROUND OF THE INVENTION

So far, the joining or anchoring of building materials has been carried out using dowels, plastic spacers, metal elements. Dowels are usually held only in solid substrates. Metal spacers are used for demanding connections and are usually screwed or other mechanical elements are used. The dowels or plastic spacers with the head only hold on solid substrates and usually require additional mechanical or reinforcing elements or adhesives. Existing types of dowels and spacers can loosen over time to the material to be attached and, by their gradual loosening, disturb the evenness of the walls.

SUMMARY OF THE INVENTION

These disadvantages are eliminated or substantially reduced by the spacer for building purposes according to the invention, which consists in that the spacer consists of at least one coil-shaped tubular element with meshes or perforations all over the surface, filled with filling material inside and outside tubular element including meshes or perforation.

It is preferred that the filler is a foamed plastic, preferably polyurethane. The filler may contain, individually or in combination, gypsum, cement, sand, lime, perlite, adhesives and binders.

It is also preferred that the tubular elements of different diameters are inserted into each other.

In preferred embodiments, the tubular element may be made of metal mesh, or of perforated sheet metal with holes or interceptions, or perforated plastic.

Furthermore, it is advantageous if the tubular element has a reinforcing element inside and in the filler mass.

It is also advantageous if the tubular element has a gripping element inserted inside and in the filler mass at one or both ends.

The main advantage of the present invention is that it allows a relatively simple and fast way of anchoring, fastening and joining all building materials such as concrete, wood, metal, brick, plaster, polystyrene, insulating materials, not only between the same materials, but also between diverse materials, without auxiliary adhesives and screws. The spacers of the present invention anchored along the entire circumference of the aperture passing through the individual materials to be joined, and thereafter the anchoring is far more efficient than the prior art anchoring with cap spacers.

The tubular element in the form of a coil has the advantage that when filling with foam or under pressure the filler material opens or expands the spacer sleeve. The filler fills not only all mesh meshes or holes or perforations in the tubular spacer, but also its interior and exterior surface. The filling material penetrates even hard-to-reach places of weathered masonry, stone, panel, etc. thereby increasing the strength and anchoring of the joint. When using a foamed plastic material, preferably polyurethane, it is preferred

It takes advantage of the polyurethane to expand very rapidly under the influence of air humidity and to increase its volume up to 30 times during foaming, thereby reliably filling all cavities and free space.

For the firm and functional connection of different materials, it is necessary to use a larger number of existing spacers according to the state of the art, yet the unevenness of the walls does not yet have to be eliminated. This drawback removes the new spacer, because the filler material fills up any unevenness, fits tightly to the respective layers and heterogeneous materials, and acts as a spacer to the individual layers to be joined. It also acts as a leveling pad.

If the materials to be joined are fundamentally different, for example in terms of their expansion under the influence of humidity, temperature and external conditions, this spacer also acts as an expansion element, and the spacer does not allow the finished surface to be disturbed.

In some cases, it is advisable to use as a filler a combination of a mixture of common building materials, such as gypsum, sand, cement, etc., by which the spacers with the material to be joined are filled under pressure. These materials require a longer curing time compared to foamed plastic. The choice of mixture depends on the type of material to be joined and is particularly suitable for concrete-concrete, brick-concrete, stone-concrete, etc. However, this type of filler is not suitable for joining plastics, wood, insulating materials and polystyrene.

The tubular element may be made of solid or mesh plastic material, metal mesh or perforated sheet metal with holes or interceptions. The use of spacer material depends on the materials to be joined. The most preferred and most widely used is a stainless steel wire spacer.

The demands on the strength of the spacer can be increased by the use of several tubular elements of different diameters, arranged in parallel with each other and in the plastic, possibly with a reinforcing element.

In some cases, if the spacer also serves to securely attach any objects to the wall, it is advantageous to use a gripping element at one or both ends.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will now be described in detail with reference to the accompanying drawings, in which: FIG. 1 shows a tubular wire element in an axonometric view; FIG. 2 shows a spacer in longitudinal section embedded in a masonry hole; FIG. 3 shows spacer with reinforcing element 4 shows two spacers with a reinforcing element, FIG. 5 a plastic spacer and FIG. 6 a spacer with a fastening element.

-2GB 290305 B6

DETAILED DESCRIPTION OF THE INVENTION

Example 1

Additional thermal insulation of buildings (Fig. 1,2).

The spacer is in the form of a tubular element 1 (FIG. 1). It is made of a woven mesh in the form of a roll, the mesh being slightly folded over the longitudinal edge of the roll. For additional thermal insulation of buildings (Fig. 2), the surface of the weathered plaster 2 is first cleaned, repaired with lime-cement mortar, an insulating board 3 is applied and the hole 4 is drilled into the masonry 5. The hole 4 is moistened with water . The tubular element 1 in the form of a roll of stainless steel mesh, woven and thus interwoven, has a length of 100 mm, a diameter of 14 mm, a mesh of about 2 mm diameter and a wire thickness of 1 mm. The tubular element 1 is completely filled with the filler material 6, in this exemplary embodiment the filler material is polyurethane foam. The spacer is then immediately inserted into the pre-drilled hole 4.

Within about 20 minutes, the foam expands, opens the coil spacer, and expands through the mesh meshes into the entire pre-drilled hole 4. After foaming the spacer with foamed plastic forms a structural anchor and spacer connecting plaster 2 up to the masonry 5 including the insulating plate 3. the connection extends over the entire length of the spacer, and the entire circumference of the opening 4, and in all of the materials to be joined. Anchoring is very stable as it fills in any irregularities and loose parts in the building material. It is not necessary to use any adhesives or other mechanical fastening for anchoring.

Example 2

Reinforcement of panel sandwiches (fig. 3).

A hole 4 is drilled through all the layers of the panel 7. In the place of the damaged panels 7, all the layers of the panels 7 are drilled to the required depth. The aperture 4 is moistened with water, and a tubular stainless steel tubular element 1 in the form of a coil, length according to the depth of the aperture 4, e.g. Locks are holes similar to those on the grater. The tubular element 1 is fully inserted into the dampened opening 4 in all layers of the panel 7 and is foamed by means of a polyurethane foam from the bottom of the opening 4 to the open end of the opening 4 by means of a special extension. After foaming, a reinforcing element 8, a stainless steel pin, is inserted into the foam to increase strength. After 20 minutes, the foam expands to form the spacer and the pin a rigid structural fastener that securely connects the panels 7 in all layers. Instead of the polyurethane foam according to the composition of the panels 7, a mixture of sand, cement and adhesive can be used as filler material 6.

-3 CZ 290305 B6

Example 3

Fixing the cornice on the facade (fig. 4).

The decorative ledge 9 on the façade of the masonry 5, made of expanded polystyrene, is adhered in several places with polyurethane foam to the underlying plaster 2, which is pre-wetted. Holes 4 are drilled into the ledge 9 thus fixed up to the wall, to a depth of 50 mm.

Let's say that the length of the hole 4 is 910 to 30 cm, 16 mm diameter, depending on the cornice profile. The wall is wet. In the drilled hole 4 drilled in this way a tubular coil-shaped element 1 made of a metal mesh, stainless steel with a corrosion-resistant finish, with a wire thickness of 1.2 mm, a mesh diameter of 3 mm, is inserted. In the case of a greater weight of the cornice 9, two tubular elements 1 of different diameters are used, which are filled with the filling material 6, namely polyurethane foam. After foaming with polyurethane foam, the two tubular elements 1 are inserted into each other. The foaming is carried out in advance and foaming only after insertion into the opening 4, which is a suitable method for a small-weight ledge 9 and using a single tubular element. of larger diameter is filled with foam inside the opening, immediately thereafter a smaller tubular element 1 of smaller diameter is inserted into the expanded foam inside the larger tubular element 1 and the expanding foam fills all the free space. The resulting spacer thus forms a structural element securely connecting the ledge 9 to the base wall.

Example 4

Connection of insulation boards 3 (fig. 5).

The joining of the insulating boards 3, where there are not so high demands on the strength of the connection, is done by a spacer, where the tubular element 1 is made of plastic mesh, eg PVC or tough polystyrene, novodur. .

Example 5

Hanging the article to a plasterboard partition 10 (Fig. 6).

The gypsum walls 10 are filled with a heat-insulating layer 11 of Prefizol-type basalt fiber. A hole 4, for example 12 mm in diameter, is drilled into this sandwich assembly to accommodate the clamp or dowel. The opening 4 is moistened with water. A wire or plastic tubular element 1 is used and polyurethane foam is used as a filler.

The spacer foamed with polyurethane foam is inserted into the dampened opening 4 and then a retaining element 12 is inserted into the spacer at its outer open end, e.g. a special spigot, which is joined to the spacer by expansion of the polyurethane foam. In such a foamed plug there is a common clamp, screw, screw, screw for attaching or hanging the object, shelf, picture, bracket, etc.

-4GB 290305 B6

Industrial applicability

The solution is designed as a connecting, anchoring or reinforcing element in the construction industry, for joining various kinds of materials, mainly flat materials including insulating ones, for repairing damaged parts of buildings, for systems of additional insulation or insulation, for interior modifications, for exterior facades and interior plasters cladding structures, ceiling tiles, solid materials, but also damaged or weathered.

Claims (10)

PATENT CLAIMS Spacer for building purposes, characterized in that it comprises at least one coil-shaped tubular element (1), with meshes or perforations over the entire surface, filled with a filler (6) inside and outside the tubular element (1) including mesh or perforation. Spacer according to claim 1, characterized in that the filling material (6) is a foamed plastic. Spacer according to claim 2, characterized in that the foamed plastic is based on polyurethane. Spacer according to claim 1, characterized in that the filler material (6), individually or in combination, contains gypsum, cement, sand, lime, perlite, adhesives and binders. Spacer according to claim 1, characterized in that the tubular elements (1) of different diameters are arranged parallel to each other. Spacer according to claim 1, characterized in that the tubular element (1) is made of metal mesh. Spacer according to claim 1, characterized in that the tubular element (1) is made of perforated sheet metal with holes or interceptions. Spacer according to claim 1, characterized in that the tubular element (1) is made of rigid perforated plastic. Spacer according to claim 1 or a combination of any of claims 2 to 8, characterized in that the tubular element (1) has a reinforcing element (8) inside and in the filler mass (6). Spacer according to claim 1 or a combination of any of claims 2 to 8, characterized in that the tubular element (1) has a gripping element (12) inserted at one or both ends of the tubular element (1).