CH720228A2 - Reinforcing element - Google Patents

Abstract

The invention relates to a reinforcing element (10) for reinforcing a concrete construction element. The reinforcing element (10) comprises at least two webs (14', 14''') which intersect one another at an intersection point, the webs (14', 14'') each being provided with at least one groove via which the webs (14', 14'') can be connected in a plug-in manner.

Description

[0001] The present invention relates to a reinforcing element, a concrete construction element and a method for laying a reinforcing element.

[0002] Punching shear and shear reinforcement systems are known for increasing the punching shear resistance of point-loaded components such as columns or wall supports in flat ceilings or floor slabs. In construction, punching shear is the term used to describe a point-like shear force failure of a reinforced concrete or prestressed concrete slab. The risk of punching shear exists when a slender, flat component is supported by a bearing with a small circumference (point bearing, columns, etc.), e.g. in the case of a flat ceiling on a column. The slab can fail in a truncated pyramid or truncated cone-shaped section around the column.

[0003] When point loads are introduced into a slab, large shear stresses are created locally. Punching is therefore a shear stress failure of the concrete and must be taken into account accordingly in the design. If a planned slab cannot mathematically absorb the shear forces from the point-like or linear introduction using the concrete load-bearing capacity alone, punching shear reinforcement is arranged in the slab in the area of the column or wall connection in order to enable sufficient load-bearing capacity.

[0004] The object of the present invention is to present an alternative reinforcing element for reinforcing a concrete structural element.

[0005] According to the invention, the reinforcing element comprises at least two webs which intersect one another at an intersection point, the webs each being provided with at least one groove via which the webs are pluggably connected. This creates a reinforcing element for increasing the shear resistance which can be simply plugged together and laid on site. The reinforcing element can also be used together with shear reinforcements to further increase the shear resistance.

[0006] The plug connection makes it possible to assemble a reinforcement element very easily and without welding. In the simplest case, the reinforcement element can be made up of two intersecting webs. Alternatively, it is possible, for example, to insert two parallel webs together into a groove of a web running transversely to the other webs. It is also possible to insert two webs arranged parallel to one another and spaced apart from one another into a pair of the same webs running transversely to one another, in a total of four places in grooves. The reinforcement element can be made of steel, for example. The reinforcement element can be designed, for example, so that it has the shape of a mushroom cap when viewed from the side.

[0007] In one embodiment of the reinforcing element, the webs intersect at an angle of 0° < β ≤ 90°, preferably β = 90°.

[0008] In one embodiment of the reinforcing element, the webs each comprise a base section and, from this, extension sections running in opposite directions. In the area of the base section, the reinforcing element reaches its full height. In the area of the extension sections, the height is reduced, e.g. conically extending. The at least one groove can be arranged in the base section, for example. This design allows less material to be used. This saves costs and weight.

[0009] In one embodiment of the reinforcing element, an upper surface of the base section runs planar to a lower surface of the respective web. In one embodiment of the reinforcing element, the extension sections extend conically tapered outwards at an angle of 0° ≤ α < 90° in relation to the upper surface of the base section.

[0010] In one embodiment of the reinforcing element, the upper surface of the base portion projects upwards in relation to the extension portions. In one embodiment of the reinforcing element, the projecting portion of the base portion is beveled with respect to the vertical of a respective web at an angle of γ ≥ 0°.

[0011] In one embodiment of the reinforcing element, the webs comprise a first web whose groove opens upwards and a second web whose groove opens downwards. In one embodiment of the reinforcing element, the groove of the first and/or second web is conically tapered.

[0012] In one embodiment of the reinforcing element, in the locked state of the two webs, the upper surface of the base portion of the first web protrudes from the upper surface of the base portion of the second web by a distance s.

[0013] In one embodiment, the reinforcing element comprises a pull ring with a recess which, when the two webs are locked, can be placed via its recess onto the projecting section of the base section of the first web. In one embodiment of the reinforcing element, the pull ring has a height which is substantially equal to the projecting distance s of the base section of the first web. In a further embodiment of the reinforcing element, the distance s is equal to 0 mm ≤ s ≤ 50 mm.

[0014] The invention further relates to a kit according to claim 14. This is a kit for creating a reinforcing element according to the invention, wherein the webs are designed in such a way that they can be connected in a plug-in manner. The webs of the kit can in particular be designed in such a way that a force-fit connection is created when they are plugged together. This makes it possible to create a reinforcing element with a certain level of complexity and can be assembled without complex connection technology, such as welding.

[0015] The invention further relates to a concrete construction element according to claim 15. This is a concrete construction element comprising a reinforcing element according to one of claims 1 to 13, wherein the intersection point of the reinforcing element is positioned in a region of a point-like load of the concrete construction element.

[0016] The invention further relates to a method for laying a reinforcing element according to one of claims 1 to 13 on a concrete element of a concrete construction element to be manufactured, comprising the steps of: connecting the two webs by plugging the two webs together via their respective grooves; and placing the reinforcing element directly or indirectly on the concrete element.

[0017] In one embodiment of the method, the step of connecting the two webs is followed by locking the two webs by placing the pull ring on the protruding portion of the base portion of the first web.

[0018] In one embodiment of the method, the reinforcing element is placed on the concrete element in such a way that the intersection point of the reinforcing element is positioned in a region of a point-like load on the concrete structural element.

[0019] Embodiments of the present invention are explained in more detail below with reference to figures. They show: Fig. 1 a reinforcing element for reinforcing a concrete construction element in a plan view, Fig. 2 the reinforcing element shown in Fig. 1 in a sectional view, Figs. 3a,b a first web in different designs, Figs. 4a,b a second web in different designs, Figs. 5a,b a tension ring in different views, and Fig. 6 the reinforcing element in a 3-dimensional view.

[0020] Fig. 1 shows an embodiment of a reinforcing element 10 for reinforcing a concrete construction element 12 in a plan view, while Fig. 2 shows the reinforcing element 10 from Fig. 1 in a sectional view. The reinforcing element 10 comprises a first web 14' and a second web 14'', which are plugged together. The webs 14', 14"' intersect essentially in the middle at an angle of essentially β = 90°. The two webs 14', 14'' are connected to one another via a tension ring 16. The reinforcing element 10 can be installed together with shear reinforcements 18'-18'''' to further increase the shear resistance. The reinforcing element 10 reduces the risk of punching under load, in particular if the concrete structural element 12 is a slender, flat component, e.g. a flat ceiling, and is supported by a column 20 or a bearing, point bearing, etc. with a small circumference.

[0021] Figs. 3a,b show the first web 14' in different designs, while Figs. 4a,b show the second web 14'' in different designs. The first web 14' comprises a groove which is opened upwards, and the second web 14'' comprises a groove which is opened downwards.

[0022] The webs 14', 14"' each comprise a base section 22', 22"' and extension sections 24', 24'' extending in opposite directions therefrom.

[0023] The respective base sections 22', 22'' comprise an upper surface which is planar to a lower surface of the respective web 14', 14''. The extension sections 24', 24'' can in turn extend outwards in a conical tapered manner at an angle of 0° ≤ α < 90° in relation to the upper surface of the base section.

[0024] While in the embodiment shown in Fig. 3a the extension sections 24' of the first web 14' extend conically tapered outwards at an angle α > 0°, e.g. α = 25°, in relation to the upper surface of the base section 22', in the embodiment shown in Fig. 3b the extension sections 24' of the first web 14' can extend outwards at an angle α = 0° in relation to the upper surface of the base section 22'.

[0025] Furthermore, while in the embodiment shown in Fig. 4a the extension sections 24'' of the second web 14'' extend outwardly at an angle α > 0°, e.g. α = 25°, in relation to the upper surface of the base section 22'', in the embodiment shown in Fig. 4b the extension sections 24'' of the second web 14'' can extend outwardly at an angle α = 0° in relation to the upper surface of the base section 22''.

[0026] The upper surface of the base portion 22', 22'' may protrude upwards in relation to the extension portions 24', 24''. The protruding portion of the base portion 22', 22'' may be beveled with respect to the vertical of a respective web 14', 14'' at an angle of γ ≥ 0°.

[0027] As previously mentioned, the groove of the first web 14' is open upwards and the groove of the second web 14'' is open downwards. For example, the grooves of the first and/or second web 14', 14'' can be conically tapered. As a result, the webs 14', 14"' that are plugged together can be connected in a force-fitting manner in the vertical direction.

[0028] When the two webs 14', 14'' are locked, the upper surface of the base section 22' of the first web 14' projects by a distance s relative to the upper surface of the base section 22'' of the second web 14''. As a result, the pull ring, which has a recess, can be placed via its recess onto the respective projecting section of the base section 22' of the first web 14' when the two webs 14', 14'' are locked, as described in detail below. The distance s can be 0 mm ≤ s ≤ 50 mm.

[0029] Figs. 5a,b show a pull ring 16 in different views, while Fig. 6 shows the reinforcing element 10 with the attached pull ring 16 in a 3-dimensional view. The pull ring 16 can have a height which is essentially equal to the protruding distance s, i.e. a height in the range between 0 mm and 50 mm. Due to the conical design of the protruding section of the base section 22', 22'' compared to the vertical of a respective web 14', 14'', e.g. with an angle of γ ≥ 0°, described in connection with the description of Figs. 3a-4b, the pull ring 16 can be connected to the protruding section in a force-fitting manner in the vertical direction.

Claims (18)

1. Reinforcing element (10) for reinforcing a concrete construction element (12), wherein the reinforcing element (10) comprises at least two webs (14', 14'') which intersect one another at an intersection point, wherein the webs (14', 14'') are each provided with at least one groove via which the webs (14', 14'') are plug-connected. 2. Reinforcing element (10) according to claim 1, wherein the webs (14', 14'') intersect at an angle of 0° < β ≤ 90°, preferably β = 90°. 3. Reinforcing element (10) according to one of the preceding claims, wherein the webs (14', 14'') each comprise a base portion (22', 22'') and extension portions (24', 24'') extending therefrom in opposite directions. 4. Reinforcing element (10) according to claim 3, wherein an upper surface of the base portion (22', 22'') is planar to a lower surface of the respective web (14', 14''). 5. Reinforcing element (10) according to claim 4, wherein the extension sections (24', 24'') extend conically tapered outwards at an angle 0° ≤ α < 90° in relation to the upper surface of the base section (22', 22''). 6. Reinforcing element (10) according to claim 4 or 5, wherein the upper surface of the base portion (22', 22'') projects upwardly in relation to the extension portions (24', 24''). 7. Reinforcing element (10) according to claim 6, wherein the projecting portion of the base portion (22', 22'') is bevelled with respect to the vertical of a respective web (14', 14'') at an angle of γ ≥ 0°. 8. Reinforcing element (10) according to one of the preceding claims, wherein the webs (14', 14'') comprise a first web (14') whose groove is opened upwards and a second web (14'') whose groove is opened downwards. 9. Reinforcing element (10) according to claim 8, wherein the groove of the first and/or second web (14', 14'') is conically tapered. 10. Reinforcing element (10) according to claim 8 or 9, wherein, in the locked state of the two webs (14', 14''), the upper surface of the base portion (22') of the first web (14') protrudes by a distance (s) relative to the upper surface of the base portion (22'') of the second web (14''). 11. Reinforcing element (10) according to claim 10, further comprising a pull ring (16) with a recess which, in the locked state of the two webs (14', 14''), can be placed via its recess onto the projecting portion of the base portion (22') of the first web (14'). 12. Reinforcing element (10) according to claim 11, wherein the tension ring (16) has a height which is substantially equal to the projecting distance s of the base portion (22') of the first web (14'). 13. Reinforcing element (10) according to claim 12, wherein the distance (s) is equal to 0 mm ≤ x ≤ 50 mm. 14. Kit for producing a reinforcing element according to one of claims 1 to 13, wherein the webs (14', 14'') are designed such that they can be connected in a plug-in manner, in particular are designed such that a force-fitting connection is created when plugged together. 15. Concrete structural element (12) comprising a reinforcing element (10) according to one of the preceding claims, wherein the intersection point of the reinforcing element (10) is positioned in a region of a point-like load of the concrete structural element (12). 16. Method for laying a reinforcing element (10) according to one of claims 1 to 13 on a concrete element of a concrete construction element (12) to be manufactured, comprising the steps: Connecting the two webs (14', 14'') by plugging the two webs (14', 14'') together via their respective grooves; and placing the reinforcing element (10) directly or indirectly on the concrete element. 17. The method of claim 16, wherein the step of connecting the two webs (14', 14'') is followed by locking the two webs (14', 14'') by placing the pull ring (16) on the projecting portion of the base portion (22') of the first web (14'). 18. Method according to claim 16 or 17, wherein the reinforcing element (10) is placed on the concrete element such that the intersection point of the reinforcing element (10) is positioned in a region of a point-like load of the concrete structural element (12).