DE9217654U1 - Lintel with reinforcement - Google Patents

Description

RICHTER, WERDERMANN & GERBAULET EUROPEAN PATENT ATTORNEYS PATENT ATTORNEYS

HAMBURG-BERLIN

DlPL ING. JOACHIM RICHTER DlPL-ING. HANNES GERBAULET DIPL-ING FRANZ WERDERMANN

-1986

NEW WALL 10 KURFÜRSTENDAMM

2OOO HAMBURG 36 1OOO BERLIN

a (0 40)34 00 45/34 00 56 ffl- (0 30)8 82 74 TELEX 2163551 INTU D TELEFAX (O 30) 8 82 32

FAX (O40) 35 24 15 in office community with

MAINITZ & PARTNER LAWYERS NOTARIES

YOUR SIGN OUR SIGN HAMBURG

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E.92591-III-1916 23.12.1992

Applicant: Elmenhorst & Co. GmbH,

2000 Schenefeld / Hamburg

Title: Lintel with reinforcement

Description

The invention relates to a facing lintel made of masonry with stretcher layers and with an underlying stretcher or rolling layer and with reinforcement embedded in the joints in the masonry mortar.

Masonry reinforcement is used for large-area walls, over window and door openings (as lintel reinforcement), for non-load-bearing partition walls on sagging ceilings, in gable masonry and in mixed masonry. In general, it is used to absorb the settling behavior of masonry wedges. Shrinkage and swelling processes can cause tensile or compressive stresses that exceed the elasticity of the masonry. As far as

If the problem cannot or should not be remedied by expansion joints, steel grids are embedded in the mortar bed in bed joints (horizontal longitudinal joints), which usually consist of parallel longitudinal bars with additional steel elements connecting them.

In the case of facing lintel reinforcements, in addition to a so-called stretcher layer, that is, bricks whose long side runs parallel to the wall when bricked up, there is also a rolling layer in which the bricks stand on the narrow side. In such masonry consisting of a rolling layer and a stretcher layer, tensile and compressive forces occur, in which the bricks are moved apart at their lower edges, whereby in the rolling layer below the upper brick edges are pressed together and the lower edges are pushed apart. This results in a force being directed into the load-bearing layer, which must be absorbed by a tensile reinforcement.

The object of the present invention is to improve a facing lintel mentioned at the outset and to create a composite system for a brick lintel between the compression and tension zones of the lintel, which accommodates the compressive stones above the reinforcement in an anchoring system that holds the stones installed under the reinforcement, so that a better distribution of the compression and tension forces is achieved in the facing lintel while at the same time preventing the masonry from sagging.

This task is solved by the facing lintel according to claim 1, whose characteristic innovation is that in order to create a bond between the compression and tension zones of the composite lintel, in which the compressive stones of the stretcher layer above the reinforcement form an anchoring

form a reinforcement system that holds the bricks of the rolling layer installed below the reinforcement, whereby the reinforcement consists of both parallel longitudinal bars and arched stirrups or plates arranged perpendicular to them, extending around the stretcher layer and into the rolling layer, whereby the stirrups guided into the stretcher layer of the facing lintel extend into the adjacent mortar or cement/mortar joint parallel to the longitudinal joint. The stirrups or full-surface steel elements, such as reinforcement plates, are perpendicular to the joint plane or the plane in which the parallel longitudinal bars lie. The particular advantage of this reinforcement is that the tensile and compressive forces that occur are directed more evenly into the masonry, in particular it prevents the facing lintels (or grenadiers) from breaking out of the masonry. The load is connected across the first layer, whereby the upper bricks are under tension.

Further developments of the invention are set out in the subclaims.

Preferably, each stirrup or plate end will end on one of the longitudinal bars. According to a further embodiment of the invention, the stirrups or plates are essentially U-shaped, which makes them ideal for vertical joints in both stretchers and rolled layers and creates the largest possible bonding surface between the steel reinforcement elements and the mortar. The stirrups themselves are made of flat or round steel.

If the brackets can be releasably clamped to the longitudinal bars, there is the further advantage that the brackets can be attached at any distance from each other and at any desired location.

This makes it possible to create individual reinforcement that is adapted to the compressive and tensile forces or stresses that actually occur.

Further advantages arise when the bracket ends are designed in a hook shape, preferably in such a way that the curvature of the hook-shaped end is matched to the longitudinal bar diameter. This ensures that the brackets can be easily hooked into predetermined places. A further improvement in terms of the positional stabilization of the brackets relative to the longitudinal bars arises when the brackets are clamped onto the longitudinal bars under a pre-tension and/or the hook-shaped ends of the brackets can be clamped onto the longitudinal bars using a snap-in closure.

A different length of the brackets or the free legs of the U-profile makes it possible, for example, to use brackets of different lengths at the top and bottom. A bracket that reaches into the runner layer can also be longer if necessary, whereby the bracket section protruding from the runner layer is then simply bent or folded over. The base of the U-shaped bracket is preferably shorter than the distance between the parallel longitudinal bars.

Preferably, at least part of the brackets extend into the adjacent mortar or cement/mortar joint that is parallel to the longitudinal joint. This means a length of the bracket that corresponds to the height of a stone plus the width of the joint.

For better anchoring, the longitudinal bars are made of ribbed steel bars, which are connected to one another by cross bars according to a further development of the invention.

The cross bars can preferably be arranged at an equidistant distance from one another.

In facing lintels in particular, it is often necessary to ensure special sealing. According to a further embodiment of the invention, angle elements are provided, which are also embedded in the mortar or cement/mortar bed. These angle elements are used to hold plastic films as lintel sealing strips, which drain the water behind the facade, for example above the windows. This angle element is embedded in the joint mortar and preferably provided with holes in order to achieve a better bond with the mortar. The supporting structure of the facing lintel is therefore not cut by the film. According to a further embodiment of the invention, the other free end of the preferably loop-shaped embedded plastic film is connected to the facing lintel elements mechanically or by gluing.

If necessary, the brackets or plates can also be made of flat steel or at least partially coated with plastic, for example to prevent corrosive attacks.

Embodiments of the invention are shown in the drawings. They show:

Fig. 1 is a perspective partially sectioned view of a facing lintel with reinforcement,

Fig. 2 a perspective view of the masonry reinforcement,

Fig. 3 a cross-section through a composite lintel with embedded reinforcement and installed lintel sealing membrane.

As can be seen from Fig. 2, the masonry reinforcement 100 that can be installed in a facing lintel 200 designed as a finished structural element consists of parallel longitudinal bars 10 and 11 that are connected by cross bars 12 that are equidistant from them at a distance a. The longitudinal bars 10 and 11 have a diameter d of, for example, 4 mm. This diameter corresponds to the diameter of the arched stirrups 13 and the cross bars 12, so that one and the same starting material can be used. However, the diameters can also be selected to be different. The stirrups 13 are perpendicular to the plane determined by the longitudinal and cross bars 10 to 12 and have different heights h depending on whether they are to be used for the grenadiers, i.e. for the rolling layer, or for the stretcher layer of the facing lintel 200 as an independent structural element (Fig. 1). The distance between the longitudinal bars b also determines the distance between the free legs of the essentially U-shaped profile, whereby the stirrup ends 14 are hook-shaped so that they can be pushed over the longitudinal bars or locked into place there. If necessary, the stirrups can also be pre-stressed. In the present case, the stirrup ends each engage the opposite inner sides of the longitudinal bars 10,11. The reinforcement 100 consisting of the longitudinal bars 10,11 and the stirrups does not need to be designed in the form of a grid. Two individual bars can also be used, which are bent and anchored in the side masonry in the support area of the facing lintel.

Figures 1 and 3 show typical facing lintels with runners 15 and grenadiers 16. The pair of longitudinal bars 10 is embedded in a layer of mortar 17 that lies between the grenadiers 16 and the runners 15 above it. The longer downward-projecting brackets 13 lie in the vertical joints between the grenadiers 16 at a distance c, i.e. limiting three grenadiers 16 each, while upward-projecting brackets 13 protrude into the vertical joints between each runner. The upward-projecting brackets 13 extend into the next mortar layer 18 between two runners, where they border on an angle piece 19 welded to a film 20. The film 20 serves as a lintel sealing membrane and drains the water behind the facade above the windows. The free end of the foil 21 is mechanically attached or glued to the ceiling. As can be seen in particular from Fig. 3, the length e of a grenadier 16 is greater than the height h of a bracket 13, while the shorter clamping brackets projecting upwards can also have a height that is greater than the height of the narrow side of a runner.

Because the stirrups can be moved on the longitudinal bars 10,11, there is no need to stick to specific joints. The butt joints of the stones can be arranged in any way, as the stirrups can be aligned to the position of the butt joints.

Claims (15)

Protection claims: 1. Lintel made of masonry with stretcher layers and with a stretcher or rolling layer underneath and with reinforcement (10 to 12) embedded in the joints (17) in the masonry mortar, characterized in that in order to create a bond between the compression and tension zones of the composite lintel, in which the compressive stones of the stretcher layer (15) form an anchoring system above the reinforcement (100) which holds the stones of the rolling layer (16) attached below the reinforcement (100), the reinforcement (100) consisting of both longitudinal bars (10, 11) running parallel to them and arched stirrups (13) or plates arranged perpendicularly thereto and extending into the stretcher layer and the rolling layer, the stirrups (13) guided into the stretcher layer (15) of the lintel extending into the adjacent mortar or Cement/mortar joint (18). 2. Lintel according to claim 1, characterized in that each bracket or plate end (14) ends on one of the longitudinal bars (10, 11). 3. Lintel according to claim 1 or 2, characterized in that the brackets (13) or plates are essentially U-shaped or V-shaped. 4. Lintel according to one of claims 1 to 3, characterized in that the brackets (13) can be releasably clamped to the longitudinal bars (10, 11). 5. Lintel according to claim 4, characterized in that
that the bracket ends (14) are hook-shaped,
preferably such that the curvature of the hook-shaped end (14) is adapted to the longitudinal rod diameter (d)
is. 6. Lintel according to one of claims 1 to 5, characterized in that the brackets (13) are clamped under a pre-tension onto the longitudinal bars (10, 11) and/or
the hook-shaped ends (14) of the brackets (13) on the
Longitudinal bars (10,11) can be clamped by means of a snap-in closure. 7. Lintel according to one of claims 1 to 6, characterized in that the brackets (13) are of different lengths. 8. Lintel according to one of claims 1 to 7, characterized in that the base piece of the U-shaped bracket (13) is shorter than the distance (b) between the parallel longitudinal bars (10, 11). 9. Lintel according to one of claims 1 to 8, characterized in that the longitudinal bars (10, 11) are connected to one another by transverse bars (12) which are preferably arranged at an equidistant distance (a) from one another.
are . 10. Lintel according to one of claims 1 to 9, characterized in that the brackets (13) or plates with
their base end adjacent to angle elements (19) which
are also embedded in the mortar or cement/mortar bed (18). 11. Lintel according to claim 10, characterized in that that the angle elements (19) serve to hold plastic films (20). 12. Lintel facing according to claim 11, characterized in that the other free end (21) of the preferably loop-shaped embedded plastic film (20) is mechanically connected to the lintel facing elements by gluing. 13. Lintel according to one of claims 1 to 12, characterized in that the brackets (13) or plates consist of flat steel. 14. Lintel according to one of claims 1 to 13, characterized in that the longitudinal bars (10, 11), transverse bars (12) and/or brackets (13) or plates are at least partially plastic-coated. 15. Lintel according to claim 12, characterized in that the angle elements (19) are provided with a perforation.