DE8714335U1 - Spacers for fastening reinforcement mesh - Google Patents

Description

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Description:

The invention relates to a spacer for fastening reinforcement grilles with a contact surface on the support element and a spacer element fastened to the contact element and provided with a recess for introducing a dowel and an expansion element.

When insulating walls of buildings, an insulating layer is applied to the outside surface of the building wall, consisting for example of rock wool. In order to protect the insulating layer from mechanical and weather influences, a layer of plaster must be applied to the free surface of the insulating layer. To hold the plaster layer and to increase its mechanical strength, a reinforcing grid is placed on the surface of the insulating layer.* This must be anchored to the wall of the building in a suitable manner. Anchoring is usually carried out using a dowel, which is inserted into a drill hole in the wall and anchored there using an expansion element. To hold the reinforcing grid to the wall of the building, a spacer has previously been used, which comprises a spacer element with a recess for inserting a dowel and an expansion element. After drilling a hole for the dowel, the spacer element is aligned with the

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The reinforcement grid is temporarily held in a drill hole, whereby the holding can be done, for example, by pressing it into the insulation layer on the wall. After the reinforcement grid has been placed on the insulation layer and is resting on the spacer element, a holding plate with a recess for the expansion element is placed on the freely accessible side, so that the reinforcement grid is now arranged between the spacer element and the holding plate. The expansion element is then inserted into the dowel.

A significant disadvantage of the spacer known from the prior art is that it is necessary to drill the hole for the dowel in the wall to be insulated before the reinforcement grid is applied. It often happens that after the ventilation grid has been arranged, it turns out that the hole was not drilled in the right place, but rather that it is positioned in relation to the reinforcement grid in such a way that a strut of the reinforcement grid runs exactly over the hole, so that the expansion element cannot be inserted. Since a large number of spacers are required to fix a reinforcement grid, such a misplacement of the hole cannot be compensated for by moving the reinforcement grid. A further disadvantage of the known spacer and the type of its fastening is that the reinforcement grid with its horizontal struts cannot be held in place by the spacer in a friction-locking manner due to the weight of the reinforcement grid, but that it is necessary to place the horizontal struts directly on the spacer and to use the

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locking element. For such support, it is also necessary to arrange the drill holes for the dowels for fastening the spacers precisely in relation to their position on the wall. However, this is practically impossible, particularly with large-area house facades. The disadvantage of the known spacer is that the reinforcement grid cannot be adequately secured to the wall with respect to the forces acting in the vertical direction. Another significant disadvantage of the known spacer is that, due to the problems described above with the arrangement of the drill holes for the individual spacers, it is not possible to use a reinforcement grid which has connecting struts or connecting wires of different diameters. In such a reinforcement grid, for example, some of the horizontally running wires or struts have a larger cross-section and serve to attach the reinforcement grid to the wall, while the remaining wires or struts have a smaller cross-section, as they only serve to anchor the plaster and protect the insulation layer. Since the position of the known spacers cannot be predetermined exactly in relation to the position of the supporting connecting wires or struts of the reinforcement grid, some spacers can only be placed exactly by chance, while the remaining spacers must interact with non-projecting areas of the reinforcement grid.

The invention is based on the object of creating a spacer of the above-mentioned type, which

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parts of the state of the art are eliminated and in which an exact view of the reinforcing grid is possible.

The object is achieved according to the invention in that the contact element is provided on the side facing the spacer element with at least one elongated holding element which extends at a distance from the contact surface and essentially parallel to it and has a free end. I

The spacer according to the invention is characterized by a number of significant advantages. Since the holding element is provided on the side of the contact element facing the spacer element I and thus the reinforcement grid, it is possible, after the insulating layer has been applied to the wall and after the reinforcement grid has been arranged, to subsequently arrange the spacer where the reinforcement grid needs to be held and stored in terms of its position and quality. The spacer is attached to the reinforcement grid using the holding element in an exactly matching arrangement and position. Only then does the hole need to be made in the wall. In this way, it is impossible for the hole to be made in the wrong place. Since the spacer can already be firmly connected to the reinforcement grid by the holding element before the hole is made in the wall to be insulated, subsequent slipping of the reinforcement grid in a vertical direction is excluded. Another significant advantage of the invention is that certain cross wires or struts of the reinforcement grid, which have an enlarged cross section,

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sen and are intended to serve for the storage of the reinforcement grid, can be brought into engagement with the spacer, which on the one hand ensures that the reinforcement grid is held particularly securely and on the other hand which allows the total number of spacers required to attach a specific area of the reinforcement grid to be considerably reduced. Both the exact positioning of the spacers and the possibility of using the spacers specifically at specific points on the reinforcement grid make it possible to considerably reduce the amount of work required to attach the reinforcement grid, so that using the spacer according to the invention results in a considerable cost advantage.

A particularly advantageous embodiment of the spacer according to the invention is provided in that two holding elements are provided which are arranged parallel to one another at a distance from one another and extend in opposite directions. In this way, it is possible to connect the spacer particularly firmly to the reinforcement grid and to prevent tilting or twisting of the spacer relative to the reinforcement grid, which could occur, for example, during the drilling process.

A further advantageous development is provided by the fact that the holding element is at a distance from the contact surface that is essentially equal to the thickness of the area of the reinforcement grid to be held. It also proves to be advantageous that the holding element in its

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free end area has a distance from the contact surface that is less than the thickness of the area of the reinforcement grid that is to be held. In this way, it is possible to fasten the spacer to the reinforcement grid without play and firmly clamped. This ensures that the hole can be drilled exactly into the wall to be insulated and that slipping of the reinforcement grid is prevented after the dowel and the expansion element have been inserted.

Advantageously, the free end areas of the holding elements are spaced apart from a straight line extending parallel to the contact surface and forming a virtual connecting line between the free end areas by at least half the thickness of the area of the reinforcing mesh to be held. With such a design, it is possible to place the spacer on the area of the reinforcing mesh to be held and to bring the area to be held, for example a brace with a reinforced cross-section, between the holding elements and the contact surface by rotating the spacer. Such an arrangement makes the assembly process on the construction site much easier.

Advantageously, the spacer is provided in one piece with a guide element arranged concentrically to the central axis of the recess, which is advantageously designed in the form of circular edge segments. Since the reinforcement grid usually has horizontal and vertical struts at the same distance, it is possible to position the spacer in exact

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The spacer can be arranged in the interior of a square formed by the struts or wires of the reinforcement grid. The circular edge segment-like design of the guide element makes it possible to rotate the spacer in a particularly simple manner after it has been inserted into a gap in the reinforcement grid in order to bring the respective holding elements into engagement with the reinforcement grid. This reliably prevents the spacer from jamming.

Because the guide element has at least one contact surface extending at a right angle to the straight line, it is particularly easy to insert the spacer into the reinforcement grid in such a way that the holding elements securely grip the respective strut or wire of the reinforcement grid. Jamming of the holding elements or incorrect gripping of the holding elements is thus reliably ruled out. Furthermore, the operator does not need to carry out any additional manipulations to align the spacer when inserting it, since this alignment is already carried out by the guide element.

Furthermore, it proves to be advantageous that the contact element is plate-shaped and is provided with handling surfaces which can be brought into positive engagement with a tool. In this way, it is possible on the one hand to minimize the thickness of the spacer outside the insulating layer and on the other hand to use a tool to securely rotate the spacer after it has been inserted into the reinforcing grid.

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thus enabling secure attachment to the reinforcement grid.

The invention is described below using an embodiment example in conjunction with the drawing. It shows:

Fig. 1 a plan view of the spacer according to the invention

Fig. 2 a side view of the spacer,

Fig. 3 is a plan view of the spacer, similar to Fig. ₁ , wherein the spacer is shown in an insertion position with respect to the reinforcing grid,

Fig. 4 is a bottom view of the spacer shown in Fig. 3,

Fig. 5 is a plan view of the spacer, similar to Fig. 1, where it is attached to a reinforcing grid and

Fig. 6 is a sectional view of the spacer of Fig. 5 along the line VI-VI as well as the wall to be insulated, the insulation layer and the plaster.

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In Fig. 1, a top view of an embodiment of the spacer according to the invention is shown, the top view of the side of the spacer facing away from a wall to be insulated being shown. The spacer has an essentially plate-shaped contact element 1, which is provided with a recess 6 for a dowel ζ and a spreading element 3 (see Fig. 6). The contact element 1 is essentially rectangular and has recesses 11 in its corner areas, which serve for engagement with a tool for rotating the spacer with respect to the axis of the recess 8. As shown in Fig. 2, an essentially tubular spacer element 4 is arranged on the contact element, the axial length of which is dimensioned to match the thickness of an insulating layer 12 (see Fig. 6). As shown in Fig. 1 and 2, the spacer has two holding elements 7, which extend essentially parallel to a contact surface 6 of the contact element. The two holding elements 7 each have a free end 7a and are designed in the form of hook-like projections. Each holding element 7 is at a distance from the contact surface 6, which is selected to match the diameter of an area 5a of a reinforcing grid 5 to be held. In the side view shown in Fig. 2, an essentially circular opening 15 is shown for receiving the area 5a of the reinforcing grid 5 to be held. The free end 7a of the holding element 7 is at a smaller distance from the contact surface 6, so that after the area 5a to be held has been introduced, it is firmly clamped or connected to the spacer. The two holding elements 7 are at a suitable distance from one another, which is dimensioned such that

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that a tilting or twisting of the contact element Ij after it has been fastened to the reinforcing grid 5 _is prevented.

In the area of the contact surface 6, the spacer is provided with a guide element 9, which extends in a circular shape over a portion of the axial length of the spacer element 4. The guide element 9 serves to guide the spacer when it is inserted into the reinforcement grid with respect to the rectangles formed by the reinforcement grid 5 and to facilitate engagement of the holding elements 7.

Fig. 1 shows a position of the spacer in which it is attached to a region 5a of the reinforcement grid 5 that is to be held and is only shown schematically by means of the holding elements 7. Figs. 3 and 4 show the spacer in a position in which it is placed on the reinforcement grid but is not yet clamped to it. The region 5a that is to be brought into engagement with the spacer and other cross struts of the reinforcement grid 5 are only shown schematically as dashed lines. The free ends 7a of the holding elements 7 are each at a distance from a virtual straight line 10, which connects the free ends 7a of the holding elements 7, which is dimensioned such that in the position of the spacer shown in Figs. 3 and 4, the area 5a to be held can be inserted between the holding elements 7. In order to facilitate the assignment of the spacer, the guide element has contact surfaces 9a, which are designed to rest on transverse strips arranged perpendicular to the area 5a.

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of the reinforcement grid 5 (see Fig. 4). In this way it is possible to insert the spacer into the reinforcement grid without having to take special precautions regarding the position of the holding elements 7.

Fig. 5 shows a view similar to the top view of Fig. l _f , but with the struts of the reinforcing grid S shown to scale.

Fig. 6 shows a section of the spacer from Fig. 5 (along the lines VI~Vi), as well as a section through a wall 14 to be insulated, as well as through the insulating layer 12 and through plaster layers 14. The dowel is inserted into the hole in the wall 13 and spread by means of the expansion element 3. The expansion element 3 thus holds the spacer on the wall 13. Furthermore, Fig. 6 shows that the area 5a of the reinforcing grid 5 to be held has an enlarged cross-section.

As shown in Fig. 1, 3 and 5, the contact element 1 has a marking line 16 on its free surface, which is arranged so that in the insertion position shown in Fig. 3 it is aligned with the area 5a of the reinforcing grid 5 to be held. By means of the marking line it is particularly easy for the operator to hold the spacer in the correct position when inserting it into the reinforcing grid 5.

In the embodiment shown, the holding elements 7 are arranged so that the contact element 1 can be moved from the insertion position shown in Fig. 3 into the position shown in Fig. 5 or in Fig. 1.

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shown inserted position must be turned clockwise. Since the expansion element 3 is usually designed in the form of a screw with a right-hand thread, the described arrangement of the holding elements 7 ensures that the spacer does not come loose from the reinforcing mesh when the screw is screwed in.

The invention is not limited to the embodiment shown. Rather, within the scope of the invention it is also possible to use only one holding element or several holding elements. It is also possible to arrange holding elements in such a way that several areas of the reinforcing grid, for example two wires or struts arranged at right angles to each other, can be gripped at the same time. The spacer according to the invention is not limited to the fastening of reinforcing grids, rather, with appropriate dimensions it is also possible to fasten other elongated structures at a distance from a wall, for example decorative cladding, plant trellises or the like.

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Claims (10)

&bull;· it f t· 4**··* &bull; · ■ t II·· ·· · &bull;IS si· ra · &bull; t 93 IB · · ■ 9 if ARNEMISSLING Dipl.-lng. &ogr; (0641) 7101S, 63 Qiessen 26 October 1987
Wed-We/Ko 87 165 GM EJOT Adolf Bohl GmbH & Co.KG, 5920 Bad Berleburg Spacers for fastening reinforcement mesh Protection claims: 1. Spacer for fastening reinforcing grids with a contact element having a contact surface and a spacer element fastened to the contact element and provided with a recess for the introduction of a dowel and a spreading element, characterized in that the contact element (1) is provided on the side facing the spacer element (4) with at least one elongated holding element (7) which extends at a distance from the contact surface (6) and is essentially parallel to it and has a free end (7a). 2. Spacer according to claim 1, characterized in that two holding elements (7) are provided, which are arranged parallel to one another at a distance from one another and extend in opposite directions. ■ 1 > i I f · » t l BKI ■ I Il I · I &bull; ■11 >) &iacgr; » &bgr; »· 3. Spacer according to claim 1 or 2, characterized in that the holding element (7) is at a distance from the contact surface (6) that is substantially equal to the thickness of the region (5a) of the reinforcing grid (5) to be held. 4. Spacer according to claim 3, characterized in that the holding element (7) has at its free end area (7a) a distance from the contact surface (6) which is less than the thickness of the area (5a) of the reinforcing grid (5) to be held. 5. Spacer according to one of claims 2 to 4, characterized in that the free end regions (7a) of the holding elements (7) are each spaced at least by half the thickness of the region (5a) of the reinforcing grid (5) to be held from a straight line (10) extending parallel to the contact surface (6) and forming a virtual connecting line of the free end regions (7a). 6. Spacer according to one of claims 1 to 5, characterized in that the spacer is provided in one piece with a guide element (9) arranged concentrically to the central axis of the recess (8). 7. Spacer according to claim 6, characterized in that the guide element (9) is designed in the form of circular edge segments. 8. Spacer according to one of claims 6 or 7, characterized in that the guide element (9) at least 4 4 * I t f « 4 444 « I 4 4 4 4 4 4 4 >« Il ( I · HtH «III I « I < ti III II« «4 I «I It Il # · &diams; *< i ■ r t i · · · HiI- Ii j «11 Ii it t desfc has a contact surface (9ä) extending at a right angle to the straight line (iO). 9. Spacer according to one of claims 1 to 8, characterized in that the contact element (1) is plate-shaped* 10. Spacer according to one of claims 1 to 9, characterized aekennzeichenofc- that the iniaaoaiomon^ (&Lgr;&Lgr; mU fs^KtSshiiisKrs is provided with handling surfaces (11) which can be brought into engagement with a tool.