EP0566539A1 - Reinforcement for masonry - Google Patents

Abstract

The invention relates to a reinforcement for a masonry structure comprising a plurality of masonry blocks (2;2a,..., 2d) which have been laid one upon the other and between which there are provided joints (3) filled with mortar, which reinforcement comprises at least one reinforcing element (1) which is arranged at least partially in one of the joints (3) and is embedded in the mortar. In order to simplify the introduction, and to improve the stability, of said reinforcement, the invention provides at least one elastically pliable longitudinal element (4) in the form of a filament and/or thin bar which consists of a concrete-compatible, tension-resistant and non-metallic material. <IMAGE>

Description

TECHNICAL AREA

The present invention relates to the field of building construction. It relates to a reinforcement for masonry consisting of a plurality of masonry stones, one above the other, between which there are joints filled with mortar, which reinforcement comprises at least one reinforcement element which is at least partially arranged in one of the joints and embedded in the mortar.

Such reinforcement is known from the prior art, for example, as a metal perforated anchor for two butt-jointing masonry walls (butt joint technology) or as a metal reinforcement in the form of a wire mesh.

STATE OF THE ART

Reinforcements for masonry essentially have two tasks: On the one hand, the reinforcement elements of a masonry wall can be embedded in the mortar of the horizontal joints in the longitudinal direction of the wall and thus increase the breaking strength of the masonry, so that the masonry walls reinforced in this way can be made thinner with the same strength.

On the other hand, they can serve as wall connection anchors to firmly connect two toothless masonry walls that abut each other at right angles. In this application, the wall anchors are placed in the joints provided for this when the one wall is bricked up so that they partially protrude from the side of the wall and can be embedded with the protruding part in the corresponding joint of the wall to be connected.

In both cases, metallic reinforcement elements are used in the prior art, e.g. consist of a galvanized iron perforated band or of galvanized or plastic-coated iron or stainless steel wires. However, various problems arise from the use of metallic materials: In general, it cannot be ruled out that the materials in the joint corrode and cause the reinforcement to weaken. Furthermore, the metallic reinforcement elements can be bent on the construction site; With longer elements, however, it is difficult to bend a once bent element back into the flat shape that is desirable for a joint. Finally, when used as a connection anchor, rigidly projecting anchors pose a considerable risk of injury; or the anchors are designed to be foldable with hinges, but the hinges form a weak point which is disadvantageous for strength.

PRESENTATION OF THE INVENTION

It is therefore an object of the present invention to provide a wall reinforcement which is easy to handle on the construction site, can be used safely, is effective and is durable.

• (a) das Bewehrungselement wenigstens ein elastisch biegsames Längselement in Form eines Fadens und/oder dünnen Stabes aufweist; und
• (b) das wenigstens eine Längselement aus einem betonverträglichen, zugfesten und nichtmetallischen Material besteht.

The task is solved in a reinforcement of the type mentioned in that

• (a) the reinforcement element has at least one elastically flexible longitudinal element in the form of a thread and / or thin rod; and
• (b) the at least one longitudinal element consists of a concrete-compatible, tensile and non-metallic material.

The essence of the invention is to use longitudinal elements made of a flexible, high-strength non-metallic material as reinforcement element, which at the same time is compatible with concrete, i.e. in particular is also alkali-resistant.

As material for the longitudinal elements, but also for the other elements used in the reinforcement, preference is given to carbon fibers or aromatic polyamides, such as are known, for example, under the trade names "Aramid", "Twaron" or "Kevlar".

• (a) eine Mehrzahl von parallel in einer Elementebene verlaufenden Längselementen vorgesehen sind;
• (b) zur Fixierung der Lage der Längselemente eine Mehrzahl von quer zu den Längselementen und untereinander parallel in der Elementebene verlaufenden Querelementen in Form von Fäden und/oder dünnen Stäben vorgesehen sind;
• (c) die Querelemente ebenfalls als Material Kohlefasern oder aromatische Polyamide enthalten; und
• (d) die Längselemente und Querelemente miteinander fest, vorzugsweise in Form eines Gewebes, verbunden sind.

A first preferred embodiment of the invention is characterized in that within the reinforcement element

• (a) a plurality of longitudinal elements running parallel in an element plane are provided;
• (b) a plurality of transverse elements in the form of threads and / or thin rods running transversely to the longitudinal elements and mutually parallel in the element plane are provided for fixing the position of the longitudinal elements;
• (c) the transverse elements also contain carbon fibers or aromatic polyamides as the material; and
• (d) the longitudinal elements and transverse elements are firmly connected to one another, preferably in the form of a fabric.

This results in a dimensionally stable, tensile reinforcement element, which can also be easily adapted to the external conditions and forms an intimate connection with the mortar of the joint.

In a further development of this embodiment, the reinforcement element has a plurality of spacers distributed in the element plane, which protrude from the element plane on at least one side and hold the reinforcement element at least on one side at a predetermined distance from the bricks, which adjoin the respective joint.

• (a) wenigsten zwei elastisch biegsame Ankerstäbe vorgesehen sind;
• (b) als Material für die Ankerstäbe Kohlefasern oder aromatische Polyamide verwendet werden; und
• (c) die Ankerstäbe im wesentlichen parallel und zuraufnahme von Scherkräften beim Uebergang von einer Mauerwerkswand zur anderen Mauerwerkswand zumindest teilweise über Kreuz verlaulen.

A second preferred embodiment, in which the reinforcement element serves as a connection anchor for two non-toothed, butt-jointed masonry walls, is characterized in that

• (a) at least two elastically flexible anchor rods are provided;
• (b) carbon fiber or aromatic polyamides are used as the material for the anchor rods; and
• (c) leave the anchor rods essentially parallel and at least partially crosswise to absorb shear forces during the transition from one masonry wall to the other masonry wall.

This type of wall anchor is flexible without a special hinge in the unconnected state and thus significantly reduces the risk of injury.

• (a) Längselemente und Querelemente zu einem Gewebe verbunden sind, welches mit den Längselementen parallel zu den Mauerwerkswänden verläuft und entsprechende Fugen beider Mauerwerkswände verbindet; und
• (b) in das Gewebe wenigstens ein elastisch biegsamer Ankerstab zur Aufnahme einer Druckbelastung eingearbeitet ist, welcher zwischen den entsprechenden Fugen beider Mauerwerkswände verläuft; und
• (c) als Material für den Ankerstab Kohlefasern oder aromatische Polyamide verwendet werden. Weitere Ausführungsformen ergeben sich aus den abhängigen Ansprüchen

A third preferred embodiment, in which the reinforcement element serves as a connection anchor for two parallel masonry walls, is characterized in that

• (a) longitudinal elements and transverse elements are connected to a fabric which runs parallel to the masonry walls with the longitudinal elements and connects corresponding joints of both masonry walls; and
• (b) at least one elastically flexible anchor rod for absorbing a pressure load is worked into the fabric and runs between the corresponding joints of both masonry walls; and
• (c) carbon fibers or aromatic polyamides are used as the material for the anchor rod. Further embodiments result from the dependent claims

BRIEF DESCRIPTION OF THE DRAWING

• Fig. 1a-c in der Seitenansicht verschiedene Ausführungsbeispiele für eine gewebeartige Mauerbewehrung mit Abstandshaltern zur Verbesserung der Einbettung in den Mörtel;
• Fig. 1d im Detail den Aufbau eines druckknopfartigen Abstandshalters gemäss Fig. 1c;
• Fig. 2a-c die verschiedenen Mauerbewehrungen gemäss Fig. 1a-c in der Draufsicht;
• Fig. 3 ein erstes Ausführungsbeispiel für einen Maueranker nach der Erfindung mit einer Kombination aus Gewebe und Ankerstäben;
• Fig. 4 ein zweites Ausführungsbeispiel für einen Maueranker nach der Erfindung mit speziell geformten Ankerstäben;
• Fig. 5 ein Ausführungbeispiel eines Mauerankers nach der Erfindung für zwei parallel verlaufende Mauerwerkswände mit einer Kombination aus Gewebe und Ankerstab; und
• Fig. 6 ein Ausführungsbeispiel für einen mit einem gewebeartigen Bewehrungselement versehenen Mauerstein.

The invention will be explained in more detail below on the basis of exemplary embodiments in connection with the drawing. Show it

• Fig. 1a-c in side view different embodiments for a fabric-like wall reinforcement with spacers to improve the embedding in the mortar;
• 1d shows in detail the structure of a push-button-like spacer according to FIG. 1c;
• 2a-c the different wall reinforcements according to Fig. 1a-c in plan view;
• Figure 3 shows a first embodiment of a wall anchor according to the invention with a combination of fabric and anchor rods.
• Figure 4 shows a second embodiment of a wall anchor according to the invention with specially shaped anchor rods.
• Figure 5 shows an embodiment of a wall anchor according to the invention for two parallel masonry walls with a combination of fabric and anchor rod. and
• Fig. 6 shows an embodiment of a brick provided with a fabric-like reinforcement element.

WAYS OF CARRYING OUT THE INVENTION

First, with the inclusion of FIGS. 1a-d and 2a-c, an embodiment of a reinforcement according to the invention will be explained, which serves for increased breaking strength within a single brick wall.

In Fig. 1a, two superposed bricks 2a and 2b of a masonry wall are shown in side view, which form a horizontal joint 3 between them. The joint 3 receives a flat reinforcement element 1, which is embedded in the mortar of the joint 3 (not shown here) and extends over several horizontally adjacent stones.

The reinforcement element 1 preferably consists of a plurality of longitudinal elements 4 (see also FIG. 2a) running parallel in one element plane in the form of threads and / or thin, elastically flexible rods, which are preferably made of carbon fibers or aromatic polyamides (in particular in fiber form). The longitudinal elements essentially absorb a longitudinal tensile load on the masonry wall.

A plurality of transverse elements 5, which likewise run parallel to one another and in the element plane, are arranged transversely to the longitudinal elements 4 and fixedly connected to the longitudinal elements in order to fix the longitudinal elements. The connection is preferably achieved in that longitudinal and transverse elements are linked together in the manner of a fabric 13.

To completely embed the reinforcement element 1 in the grout and thus the maximum To achieve tensile strength of the wall, spacers 6 are provided in the reinforcement element 1 distributed over the element level, which ensure that the longitudinal elements 4 which are decisive for the strength have sufficient distance from both wall stones 2a and 2b in order to be sufficiently surrounded by the mortar on all sides.

In the exemplary embodiment in FIGS. 1a and 2a, the spacers 6 are formed in that the transverse elements 5 are deformed in a zigzag manner (for example by a deformation process). This results in a particularly easy to manufacture reinforcement element 1 with integrated spacers, which can also be rolled up in almost any length for transport.

In the exemplary embodiment in FIGS. 1 b and 2 b, the fabric 13 or the lattice of longitudinal and transverse elements is formed from both sides with thickenings which can be round, square, elongated or of another shape and can run in the longitudinal direction, obliquely or transversely . The thickenings can be made of a plastic that is compatible with concrete.

In the exemplary embodiment in FIGS. 1c and 2c, the spacers 6 - as shown in detail in FIG. 1d - each consist of an upper part 7a and a lower part 7b, which are formed by means of a snap-in nose formed on a part (7a or 7b) in the manner of a push button inserted from both sides through a mesh of the grid formed from the longitudinal elements 4 and transverse elements 5 and connected to one another in a snap-in manner. The advantage of these spacers is that they can be manufactured separately and can be attached to the reinforcement element 1 in a particularly simple manner by machine.

In the exemplary embodiments described above, the spacers 6 could also be designed such that they protrude from the element plane essentially only on one side, for example downwards towards the brick 2b.

3 and 4 reinforcement elements 1 are shown, which have the task of connecting anchors in the butt joint technique. In the butt joint technique, two masonry walls 11a and 11b arranged at right angles to each other butt out, i.e. butted against each other and are only positively connected to each other by appropriate connection anchors (reinforcement element 1).

In the exemplary embodiment in FIG. 3, the corresponding reinforcement element 1 has a structure that combines a fabric 13 with at least two anchor rods 8a and 8b. The fabric 13 in turn consists of interconnected longitudinal and transverse elements 4 and 5. The anchor rods 8a and 8b are braided into the fabric 13 in the element plane. They are preferably made from carbon fibers or aromatic polyamides and have e.g. a diameter of 3 mm. It is particularly favorable for a firm connection with the joint mortar to make the anchor rods 8a, b, like all other rod shapes used in the reinforcement element, with a rough surface in order to improve the interlocking between the rod and the mortar.

The reinforcement element 1 of FIG. 3 is embedded with a first partial length in a joint of the first masonry wall 11 a, that a second partial length initially protrudes laterally and then embedded in a corresponding joint of the second masonry wall 11 b when bricking up the second masonry wall 11 b can. The anchor rods 8a and 8b are arranged to absorb transverse forces in such a way that they cross at the transition from one masonry wall 11a to the other masonry wall 11b. Here, too, it is advantageous to provide the spacers 6 known from FIGS. 1a-c in order to optimize the embedding in the mortar.

The reinforcement element 1 of FIG. 4 does not require a fabric. In this embodiment, at least two anchor rods 9a and 9b form the longitudinal elements 4. One (outside) anchor rod 9a absorbs the tensile and compressive forces, the other (inside) anchor rod 9b crosses over at the transition from one masonry wall 11a to the other masonry wall 11b and mainly absorbs lateral forces. Both anchor rods 9a, b form a closed loop on the side facing the adjoining masonry wall 11b, so that no rod ends protrude outwards. The anchor rods 9a, b are bent outwards within the masonry wall 11a in order to improve the introduction of force. Fixing brackets 10a-c are preferably used to fix the position of both anchor rods 9a, b, which also serve as spacers within the joint.

It goes without saying that not only the reinforcement element shapes shown in FIGS. 3 and 4 are suitable for the butt joint technique, but other configurations of two or more anchor rods are also conceivable within the scope of the invention.

5 shows a further exemplary embodiment of a reinforcement according to the invention, which relates to the mutual anchoring of two parallel masonry walls 17a and 17b. Such an application is given, for example, when a pre-built second masonry wall 17b made of thin clinker bricks 12a-d with a wall space 16 is to be attached to a first masonry wall 17a made of normal masonry stones 2a-d. The example in turn is based on a fabric 13 consisting of longitudinal and transverse elements 4 and 5 (shown in FIG. 5 only in the right half), in which ches at least one elastically flexible anchor rod 14 is braided in a wave shape. The wave amplitude is chosen so that the anchor rod 14 is alternately embedded in the joints of the two masonry walls 17a and 17b. To fix the anchor rod 14, fixing brackets 15a-c can also be provided which act as spacers and have corresponding bores for the anchor rod 14 to pass through.

The fabric 13 serves to anchor both masonry walls 17a, b to one another, but also to reinforce the individual walls in the longitudinal direction. If such reinforcement can be dispensed with, it is also conceivable to use reinforcement element 1 without fabric 13.

Finally, in Fig. 6 an embodiment is shown in which a brick 2 from the outset, i.e. Factory-made, is firmly connected on one side with a preferably fabric-shaped reinforcement element. The fabric 13 protrudes beyond the brick 2 at least on one transverse side and thus overlaps the brick adjacent on the same level when inserted into a brickwork. If this is also provided with such a fabric 13, it is advantageous if the fabrics 13 of the two bricks overlap each other. If the horizontal joint formed above the stones is then filled with mortar, the reinforcement extends from stone to stone, which increases the breaking strength of the masonry. Especially with large-sized stones made of gas concrete or the like, it is advisable to glue the reinforcement element directly to the stone. But it is also conceivable to embed the reinforcement element in the stone during the manufacture of the brick 2.

As already mentioned at the beginning, materials based on aromatic polyamides are used for the fabric 13, the longitudinal elements 4, the transverse elements 5 and the anchor rods 8a, b, 9a, b and 14, which are known under the names "Aramid", "Kevlar" or "Twaron" are known. These materials are then processed into tissue in the form of thin fibers or used directly in the form of a rod.

Overall, the invention results in a wall reinforcement that is easy to manufacture, durable, easy to use and versatile.

LIST OF DESIGNATIONS

• 1 reinforcement element
• 2 brick
• 2a, .., 2d brick
• 3 fugue
• 4 longitudinal element
• 5 cross element
• 6 spacers
• 7a upper part (spacer)
• 7b lower part (spacer)
• 8a, b anchor rod
• 9a, b anchor rod
• 10a, b, c fixation bracket
• 11a, b masonry wall
• 12a, .., 12d clinker brick
• 13 tissues
• 14 anchor rod
• 15a, b, c fixation bracket
• 16 space between walls
• 17a, b masonry wall

Claims (15)

1. Reinforcement for masonry from a plurality of masonry stones (2; 2a, .., 2d), between which there are joints (3) filled with mortar, which reinforcement comprises at least one reinforcement element (1), which is at least partially in one of the joints (3) is arranged and embedded in the mortar, characterized in that (a) the reinforcement element (1) has at least one elastically flexible longitudinal element (4) in the form of a thread and / or thin rod; and (b) the at least one longitudinal element (4) consists of a concrete-compatible, tensile and non-metallic material. 2. Reinforcement according to claim 1, characterized in that carbon fibers or aromatic polyamides are used as the material for the longitudinal elements. 3. Reinforcement according to claim 2, characterized in that within the reinforcement element (1) (a) a plurality of longitudinal elements (4) running parallel in an element plane are provided; (b) to fix the position of the longitudinal elements (4), a plurality of transverse elements (5) running transversely to the longitudinal elements (4) and mutually parallel in the element plane are provided in the form of threads and / or thin rods; (c) the transverse elements (5) also contain carbon fibers or aromatic polyamides as the material; and (d) the longitudinal elements (4) and transverse elements (5) are firmly connected to one another, preferably in the form of a fabric (13). 4. Reinforcement according to claim 4, characterized in that the reinforcement element (1) distributed in the element plane has a plurality of spacers (6) which protrude from the element plane on at least one side and the reinforcement element (1) at least on one side at a predetermined distance hold to the bricks (2; 2a, .., 2d), which are adjacent to the respective joint (3). 5. Reinforcement according to claim 4, characterized in that the spacers (6) are formed by a zigzag-shaped buckling of the transverse elements (5) out of the element plane. 6. Reinforcement according to claim 4, characterized in that thickenings are provided as spacers (6), which are formed on the grid of longitudinal elements (4) and transverse elements (5). 7. Reinforcement according to claim 4, characterized in that the spacers (6) each consist of an upper part (7a) and a lower part (7b), and by means of a snap-on nose formed on a part (7a or 7b) in the manner of a push button both sides are inserted through a mesh of the grid formed from the longitudinal elements (4) and transverse elements (5) and connected to one another in a snap-in manner. 8. Reinforcement according to claim 2, in which the reinforcement element (1) serves as a connection anchor for two toothless, butt-butting masonry walls (11a, b), characterized in that (a) at least two elastically flexible anchor rods (8a, b or 9a, b) are provided; (b) carbon fibers or aromatic polyamides are used as the material for the anchor rods (8a, b or 9a, b); and (c) the anchor rods (8a, b and 9a, b) are substantially parallel and at least partially crosswise to absorb shear forces during the transition from one masonry wall (11a) to the other masonry wall (11b). 9. Reinforcement according to claim 8, characterized in that (a) a plurality of longitudinal elements (4) running parallel in an element plane are provided; (b) to fix the position of the longitudinal elements (4), a plurality of transverse elements (5) running transversely to the longitudinal elements (4) and mutually parallel in the element plane are provided in the form of threads and / or thin rods; (c) the transverse elements (5) also contain carbon fibers or aromatic polyamides as the material; (d) the longitudinal elements (4) and transverse elements (5) are connected to one another in the form of a fabric (13); and (e) the anchor rods (8a, b) are woven into the fabric (13). 10. Reinforcement according to claim 8, characterized in that (a) the anchor rods (9a, b) themselves form the longitudinal elements (4); and (b) transverse fixing brackets (10a, b, c) are provided for fixing the position of the anchor rods (9a, b). 11. Reinforcement according to claim 3, wherein the reinforcement element (1) serves as a connection anchor for two parallel masonry walls (17a, b), characterized in that (a) Longitudinal elements (4) and transverse elements (5) are connected to a fabric (13), which with the Longitudinal elements (4) run parallel to the masonry walls (17a, b) and connect corresponding joints of both masonry walls (17a, b); and (b) at least one elastically flexible anchor rod (14) is incorporated into the fabric (13) for receiving a pressure load, which runs between the corresponding joints of the two walls of the brickwork (17a, b); and (c) carbon fiber or aromatic polyamides can be used as material for the anchor rod (14). Reinforcement according to claim 11, characterized in that a single, continuous anchor rod (14) is used, which is curved in a wave shape. 13. Reinforcement according to claim 12, characterized in that for fixing the position of the anchor rod (14) additionally extending in the longitudinal direction fixing bracket (15a, b, c) are provided. 14. Reinforcement according to claim 3, characterized in that at least one reinforcement element (1) is attached to a brick (2) in such a way that part of the reinforcement element (1) when inserting the brick (2) into a brickwork on the same level adjacent brick and vorzuasweise the reinforcement element (1) attached to this overlaps. 15. Reinforcement according to one of claims 1 to 14, characterized in that at least the rods or anchor rods (8a, b; 9a, b; 14) used in the reinforcement element (1) have a roughened surface to improve the connection with the mortar.

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