DE19714435A1 - Porous concrete blockwork with reinforcing grids - Google Patents

Abstract

Flat-rolled expanded metal grids (3) are embedded in a thin layer of mortar (4) applied to the surface (2a) of porous concrete blockwork in the area of the tension zone, to provide reinforcement. Preferably, several strips of expanded metal, about 15 cm wide, are positioned vertically, spaced from each other on the inside of a cellar wall (1) subject to earth pressure, and are bonded to the blockwork surface by mortar. The expanded metal preferably made of stainless steel and the mortar has a compression strength of at least 10 N/mm<2>.

Description

The invention relates to reinforced masonry, ins special from aerated concrete blocks, using of metal reinforcement bars.

Masonry walls can result from earth pressure or wind pressure exerted perpendicular to the wall plane sets, so that a bending load capacity lower right to the wall level is required. By earth pressure There is a load on the inside of a basement wall a tensile load. To absorb this strain it is known to have masonry with reinforcement bars to armor that when masonry masonry in the bed joints are inserted. The so-called Murfor reinforcement mesh consists of two parallel walls finned ribbed longitudinal wires of 5 mm in diameter, through a welded zigzag shape and manufactured connecting wire of 3.75 mm in be kept constant distance. This Murfor reinforcement grid are in the bedding of wall plant embedded (see magazine "ZIEGELINDUSTRIE INTERNATIONAL "2/86, pages 62-64). For walls, which are bricked with special shaped stones or blocks which are parallel to the butt joints Have recesses, it is also possible a vertical section running across the entire wall to incorporate the reinforcement. This vertical reinforcement exists from individual reinforcing bars that are in the recess mations of the shaped stones are arranged, then the recesses are filled with mortar. That on masonry walls with such vertical blows Rungsstäben is quite time consuming, however, because the individual bricks from above on the reinforcement rods need to be threaded and then the off  savings must be filled with mortar. Furthermore is the reinforcement in the middle, neutral Zone of masonry arranged and therefore not very effective. The Murfor reinforcement grid has been used for thin bed mortar grout, as in masonry made of aerated concrete blocks used, not proven. For use in Thin bed mortar joints are the wires to one Flat rolled thickness of 2 mm, but only one insufficient bond property between the reinforcement grid and the thin-bed mortar reached so that the mutual power transmission between the masonry and the reinforcement grid is insufficient. Furthermore is the total cross section of the reinforcement grid low to the occurring tensile forces in the direction to be able to accommodate the bed joint.

EP 681 071 A1 describes a reinforcement mesh for Masonry joints known from a sheet metal strip by making oblique cuts or slits between at least two longitudinal strips and transverse stretching between the cuts or Slits created webs is formed. Such one Reinforcement mesh has the appearance of expanded metal. After stretching the sheet metal strip, this is between two counteracting rollers first flattened rolls and then immediately in a profiling machine direction, which two interacting rollers with gear-like profile, again with cross Profiles arranged in the direction of travel provided by waves to the adhesion or claw properties of the reinforcement mesh in the later Improve use in masonry.

The invention has for its object a reinforced Masonry, especially from aerated concrete blocks of the one way mentioned above, which in simple Wise and simple to manufacture and thereby absorbing considerable bending tensile stresses suitable is.

This is achieved according to the invention in that the reinforcement mesh made of flat-rolled expanded metal mesh which exists in the area of the draft zone of the masonry arranged on its surface and in one on the Surface applied layer of thin-bed mortar is embedded.

The invention is therefore based on the idea that Reinforcement mesh flat rolled expanded metal to ver turn and this reinforcement grid no longer like common with previous steel reinforcements, in Inside the masonry but on its surface to attach. This attachment to the surface is very easy, because the masonry can do just like unreinforced masonry regardless of any Reinforcements are bricked up, whereby also large matt aerated concrete blocks with the help of suitable Hoists can be moved. Only when that Masonry is finished, the reinforcement grids in the form of flat rolled expanded metal grids in the area of the draft zones of the masonry using thin bed mortar on the surface of the masonry, so to speak "glued". Through this thin bed mortar, which is also in penetrates the mesh of the expanded metal grid a very strong connection between this and the masonry. The arrangement of the stretch metal grid on the surface of the masonry not only the advantage that the expanded metal grid  can be easily installed after the masonry has been erected, but also the further advantage that the stretch metal grid in that area of the draft zone det where the greatest pulling forces occur. It is therefore with regard to the absorption of the tensile forces effective. That is why individual expanded metal grids can also be used strips that are used at greater intervals distributed from each other on the surface of the masonry to be ordered. The flat rolled expanded metal grid is only about 0.7 to 1.2 mm thick and wears because it has a very thin layer of thin bed mortar with the surface of the masonry is connected to very little. It can therefore by applying a plaster layer of usual thickness be covered, and is then no longer outwardly visible.

The new type of reinforcement can also be used in production of lintels for windows and doors with advantage be set. For this purpose it is flat rolled Expanded metal at the bottom of a brick wall Fall arranged from several, at their joint surfaces bonded together using thin-bed mortar bricks, especially aerated concrete blocks, consists. In this way you can fall with produce a particularly low overall height.

Advantageous embodiments of the invention are shown in characterized several sub-claims.

The invention is in the following, based on in the Drawing illustrated embodiments closer explained.  

Show it:

Fig. 1 shows the cross-section of a masonry wall with reinforcing Keller,

Fig. 2 is a partial interior view of the basement wall in Rich processing II of Fig. 1,

Fig. 3 is a partial cross section of a masonry stone with the reinforcement arranged thereon,

Fig. 4 a fall over a window or door opening.

In FIGS. 1-3, the invention is explained using the example of a loaded from the earth pressure basement wall. This basement wall 1 consists of masonry, which is built up from individual NEN bricks, expediently from aerated concrete blocks 2 , using thin bed mortar. From the outside, this cellar wall 1 is loaded by the earth pressure E and is thus subjected to bending. This bending stress generates bending tensile stresses in the area of the inner surface 2 a of the masonry facing the building. In order to absorb the tensile forces, a plurality of expanded metal grid strips 3 are arranged on the inner surface 2 a of the cellular concrete blocks 2 . These expanded metal mesh strips consist of flat-rolled expanded metal mesh, which is expediently made of stainless steel. The expanded metal grid strips are embedded in a layer 4 of stone on the inner surface 2 a of the wall made of thin-bed mortar, so that the thin-bed mortar, as shown in Fig. 3, also penetrates into the mesh of the expanded metal grid 3 . So that a power transmission is ensured everywhere from the expanded metal grid strip 3 to the thin-bed mortar, in practice after pressing in the expanded metal grid strip 3 in the thin-bed mortar 4 further thin-bed mortar on the outside of the expanded metal grid strip 3 is carried up and smoothed out. Overall, an approximately 1.5 mm thick layer of thin-bed mortar 4 is formed , in which the expanded metal grid strips 3 are embedded so that at least the meshes or openings in the expanded metal grid strip 3 are completely filled with thin-bed mortar. As a result, in addition to an adhesive bond, a positive connection between the expanded metal grid 3 and the thin-bed mortar is also provided. Thanks to its good adhesion properties, the thin-bed mortar 4 also adheres excellently to the upper surface 2 a of the bricks 2 , so that a very good and durable, tensile connection is created between the brick 2 and the expanded metal grid 3 .

The expanded metal grid strips 3 should cover about 30% of the inner surface 2 a of the basement wall. Approx. Two expanded metal grid strips with a width b of approximately 15 cm are arranged on a wall width of 1 m. Depending on the bending tensile stress that occurs, the number of strips, their spacing and / or their width can be selected accordingly.

The expanded metal grid strips 3 are expediently glued vertically to the inner surface 2 a by means of the thin-bed mortar 4 , as shown in FIG. 2. However, it is also possible to arrange the expanded metal grid strips running horizontally.

Fig. 4 shows the application of the invention, Figure 5 shows bridging fall 6 for a window or a door opening. This lintel consists of several aerated concrete blocks 2 , which are connected to one another at their abutting surfaces by means of thin-bed mortar. On the underside 2 a of these aerated concrete blocks 2 , an expanded metal grid 3 'is in turn glued using thin-bed mortar 4 , this expanded metal grid 3 ' being embedded in the thin-bed mortar 4 in the manner described above. The expanded metal grille 3 'extends over the full width of the window or door opening 5 . The expanded metal grid 3 'should extend into the masonry on both sides of the window or door opening 5 serving as a support.

In practice, such a lintel 6 can be made so that when the masonry has reached the height of the lintel to be manufactured, the window or door opening 5 is covered with a board supported downwards. A film is placed on this board and a layer of thin-bed mortar 4 is applied to it and to the stones serving as supports. The expanded metal grid 3 'is embedded in this layer and a thin layer of thin-bed mortar is again applied to the expanded metal grid. Then the bricks 2 forming the lintel are placed, with thin bed mortar also being inserted between their joint surfaces. After the thin-bed mortar has hardened, the board and foil are removed. One can also proceed in such a way that first a layer of thin, about 2-3 cm thick aerated concrete blocks is placed on the board instead of the film, then thin-bed mortar is applied to these aerated concrete blocks and the adjacent aerated concrete blocks serving as supports, then the expanded metal grid 3 ' embedded in the thin-bed mortar and then proceed as described above. In this case, the thin aerated concrete blocks only serve to prevent the thin-bed mortar from sticking to the board underneath and later they serve as a plaster base. However, they have no supporting function. The expanded metal grid takes over the tensile forces resulting from the load, while the compressive forces are absorbed by the cellular concrete blocks 2 .

If necessary, the lintel formed from the aerated concrete blocks 6 can also be prefabricated at the factory and the expanded metal grid strip 3 'made of flat-rolled expanded metal can be connected to the lintel 6 using thin-bed mortar.

The thin-bed mortar used to connect the expanded metal grid strips to the masonry should have a compressive strength of at least 10 N / mm ^2. In practice, it has been shown that thin-bed mortar, as is usually used for masonry of aerated concrete blocks in the thin-bed mortar method, can also be used for bonding the expanded metal grid strip with the surface 2 a of the aerated concrete blocks 2 is suitable.

Claims (10)

1. Reinforced masonry, in particular made of aerated concrete, using reinforcing mesh made of metal, characterized in that the reinforcing mesh consists of flat-rolled expanded metal mesh ( 3 , 3 '), which in the area of the tensile zone of the masonry ( 1 , 6 ) on its surface (2 a) arranged and embedded in a recessed on the surface placed layer of thin-bed mortar (4). 2. Masonry according to claim 1, characterized in that on the inside of a basement wall exposed to earth pressure ( 1 ) a plurality of expanded metal grid strips ( 3 ) spaced apart and by means of thin-bed mortar ( 4 ) with the inwardly facing surface ( 2 a) of the bricks ( 2 ) are connected. 3. Masonry according to claim 2, characterized in that the expanded metal grid strips ( 3 ) cover about 30% of the inner surface ( 2 a) of the basement wall ( 1 ). 4. Masonry according to claim 3, characterized in that the expanded metal grid strips ( 3 ) have a width of about 15 cm. 5. Masonry according to one of claims 2 to 4, characterized in that the expanded metal grid strips ( 3 ) are arranged to run vertically. 6. Masonry according to one of claims 2 to 4, characterized in that the expanded metal grid strips ( 3 ) are arranged to run horizontally. 7. Masonry according to claim 1, characterized in that the flat-rolled expanded metal grid ( 3 ') on the underside ( 2 a) of a brick lintel ( 6 ) is arranged, which from several at their joint surfaces by means of thin-bed mortar interconnected which bricks ( 2 ) , in particular aerated concrete blocks. 8. Masonry according to claim 7, characterized in that the lintel ( 6 ) is prefabricated. 9. Masonry according to one of claims 1 to 8, characterized in that the expanded metal grid ( 3 , 3 ') consists of stainless steel. 10. Masonry according to one of claims 1 to 8, characterized in that the thin-bed mortar ( 4 ) has a compressive strength of at least 10 N / mm ² .