EP4015732A1 - Support element for a prefabricated reinforced concrete part - Google Patents

Abstract

The invention relates to a support element for a prefabricated reinforced concrete component. The support element has a steel beam with a support area or a support plate. The steel girder is integrally connected to a receiving element, which carries an anchoring element protruding from the steel girder.

Description

The invention relates to a support element for a precast reinforced concrete part, which has a steel girder with a support area or a support plate and the steel girder is integrally connected to a receiving element which carries an anchoring element protruding from the steel girder.

Furthermore, the invention relates to a precast reinforced concrete part with a support element and a method for producing a support element. Prefabricated reinforced concrete parts with a longitudinal extension are known, which are placed on supporting components such as consoles or on supporting structures such as beams, columns, beams or the like. The above-mentioned support elements are located at the ends of the precast reinforced concrete part and produce a mechanical connection between the precast reinforced concrete part and the supporting structure.

A generic support element is from the European patent application EP 685 608 A1 known. This document describes a support element for a prefabricated reinforced concrete part, which has a steel girder with a sleeve welded to its lower chord. An internal thread is cut on the open side of the sleeve.

An anchoring element rod, which is a reinforcement rod with a welded-on anchor plate, has an external thread at its other end, via which it is screwed into the sleeve. So that a reinforcing bar can be used accordingly, it must first be prepared. In particular, the rod must be upset in one area. Then the ribs typical of the rebar are peeled off on the lateral surface in the area where the thread is to be applied.

Then the rod is chamfered at the end and a thread is rolled or cut. The large number of processing steps makes this product more expensive. Screwing in the loose tie rod with a predetermined torque is also expensive.

The invention has set itself the task of proposing a support element whose production is cheaper and which is then easier to assemble on site.

To solve this problem, the invention is based on a support element, as described above, and proposes that a receiving element is pressed onto the anchoring element.

The proposed press connection between the receiving element and the anchoring element increases safety in the production of precast reinforced concrete parts with such supporting elements. The user no longer has to make a screw connection whose tightening torque must be checked with a suitable tool. This proposal achieves the same viability as the prior art.

The receiving element is preferably designed as a sleeve. However, it is also possible to use a different body with an outer cross-section instead of a circle, such as a square or a polygon, instead of a pressed-on, rotationally symmetrical sleeve, in which the anchoring element is inserted and fastened in a bore. The type of attachment can be welding or pressing or other form and adhesion. It is crucial that the reinforcement bar is not welded directly onto the steel girder, because this requires very thick and multi-layer weld seams in order to create the frictional connection over the entire surface. In the case of a receiving element, which can form a kind of intermediate piece between the reinforcing bar and the steel girder, which has a larger circumference for welding, the weld seam can be thinner and single-layered because it becomes longer. This means that less heat is introduced and the welding is significantly accelerated

The anchoring element is connected to the steel girder via the pressed-on receiving element, preferably by welding. Since the receiving element receives the anchoring element, the connection edge and the connection surface available for the welding are thereby increased. This facilitates the angular connection between the anchoring element and the steel beam.

Due to the pressing process on the one hand and the welding on the other hand, the alignment of the end anchorage (= anchor plate) arranged on the anchoring element is secured against torsion, which is particularly advantageous in the thin webs of prestressed reinforced concrete parts.

• Aufpressen eines Aufnahmeelementes auf ein Verankerungselement
• einstückiges Verbinden des Aufnahmeelementes mit dem Stahlträger des Auflageelementes

The object according to the invention is not only achieved by the support element described, but also by a method for producing a support element as a steel component of a precast reinforced concrete part, which is characterized by the following steps:

• Pressing a receiving element onto an anchoring element
• integral connection of the receiving element with the steel beam of the support element

In the case of the proposals in the prior art, a sleeve had to be welded to the steel girder first. Then an internal thread had to be cut into the sleeve. If a reinforcing bar was used as the anchoring element, it first had to be compressed, chamfered or peeled, i.e. the ribs in the area of the lateral surface that was to protrude into the sleeve had to be removed. After the peeling process, an external thread had to be applied to the rebar, and only then could the rebar be screwed into the internal thread of the sleeve while precisely controlling the tightening torque.

The method proposed according to the invention considerably shortens this complex process according to the prior art and therefore makes the production of a support element according to the invention considerably cheaper. A further checking step for the correct rotational alignment of the end anchorage or the anchoring element on the support element is also omitted.

In a preferred implementation of the method, it is provided that first the receiving element is pressed onto the anchoring element and only then is the receiving element integrally connected to the pressed-on anchoring element on the steel girder, preferably welded.

Alternatively, however, the invention also encompasses a different method sequence. The invention also includes a solution in which first a receiving element that is also relatively large, i.e. long in relation to the diameter (ratio of length to outer diameter greater than 2.5, preferably greater than 4, particularly preferably greater than 5) is welded onto the steel girder and only then the anchoring element is inserted into the welded-on receiving element and pressed with it.

Furthermore, it is advantageously provided in the proposal that the receiving element is welded to the steel girder or is welded to it. The welding is preferably carried out with a fillet weld (encircling the circumference of the receiving element). Alternatively, it is provided that a one-piece connection is also made by another joining process such as flash butt welding, laser welding or friction welding.

In a preferred embodiment of the proposal, it is provided that there is a free space between the end surface of the anchoring element protruding into the receiving element and the steel girder. Due to the receiving element having a larger diameter than the anchoring element, the weld is accelerated on the one hand due to the increase in seam length with less weld metal application and on the other hand the quality is improved.

Since the anchoring element does not protrude as far as the steel girder, less heat is dissipated during welding. At the same time, the lower heat input also minimizes the risk of damage to the cold-formed pressing area and thus misalignment. Furthermore, through the "insulation effect" or the lower heat input due to the arrangement of the free space avoids a temperature-related, negative effect on the press connection.

Such a configuration is achieved in that, in the method proposed according to the invention, the receiving element is not pushed completely onto the anchoring element, but rather a free space remains above the end face of the anchoring element in the receiving element.

Furthermore, it is provided that the pressed-on section of the receiving element is as long as or shorter than the insertion length of the anchoring element in the receiving element. It has been found that it is sufficient that a press connection is not necessary over the entire standing length of the anchoring element in the receiving element, but that a smaller part is already sufficient to achieve a stable connection. For example, the standing length is 50-80%, preferably 60-70%, of the axial length. The length of the pressed-on section of the receiving element is approximately 45-75%, preferably 50-60%, of the axial length. The pressed-on section is designed in such a way that the end region of the anchoring element (for example a reinforcing bar) protruding into the receiving element is not pressed.

The press connection, or the pressed-on section, is preferably located on the side of the receiving element facing away from the steel girder. As a result, the pressing is not directly exposed to the heat input during welding and is thermally protected in particular by the free space. The pressing remains sufficiently mechanically resilient even after welding.

It is possible to use a different body with an outer cross-section instead of a circle, such as a square or a polygon, in which the anchoring element is inserted into a bore and fastened, as the receiving element instead of a pressed-on, rotationally symmetrical sleeve. The type of attachment can be welding or pressing or other form and adhesion. It is crucial that the reinforcement bar is not welded directly onto the steel girder, because this requires very thick and multi-layer weld seams in order to create the frictional connection over the entire surface. If there is an intermediate piece between the rebar and the steel beam that has a larger circumference for welding, the weld seam can be thinner and single-layered because it becomes longer. This means that less heat is introduced and the welding is significantly accelerated.

In an advantageous embodiment, it is provided that the anchoring element is designed as a bar, in particular as a reinforcing bar or as a bar with ribs on the lateral surface. The ribs on the lateral surface of a rebar considerably improve the anchoring of the anchoring element in the concrete of a prefabricated reinforced concrete part. However, the ribs also significantly improve the hold of the anchoring element in the pressed-on receiving element. The pressing forces used are so high that the material of the receiving element is plastically deformed and rests against the surface of the anchoring element around the ribs, thus resulting in a form-fitting bond, similar to the bond in concrete. This is also a great advantage of this variant, since in comparison to the prior art the ribs had to be peeled off first and then on Thread was to apply. In the proposal according to the invention, both in the form of the object and in the method, the reinforcing bar with the ribs can remain as is and an equally load-bearing result is obtained with little effort.

Cleverly, it is provided that the anchoring element has an end anchorage at its end remote from the receiving element. A plate, hook, anchor plate or washer is provided as the end anchorage, for example, which is welded or upset onto the anchoring element.

In a further preferred embodiment it is provided that the steel girder has an upper chord and a lower chord and the anchoring element preferably projects at right angles to the lower chord. Depending on the installation situation of the support element in the precast reinforced concrete part, any other orientation of the anchoring element relative to the steel girder is of course also covered by the invention.

Furthermore, it is advantageously provided that the steel girder as a profile product, in particular as an I; T-; Double-; U-; Double U or rectangular profile is formed. The invention is very variable and versatile in the selection of the profile of the steel beam.

It is advantageously provided that the steel girder has a longitudinal extension and the support area or the support plate is provided at one end of the longitudinal extension.

Furthermore, the proposal advantageously provides for the support plate to be welded to the steel girder, in particular to the bottom chord of the steel girder. This serves to center the load away from the edge in the area of support on the supporting structure, such as a beam or bracket. This avoids force peaks on the edge of a support element. If necessary, the support plate is made wider than the steel girder or the lower chord of the steel girder, in order to reduce the compressive load on the concrete.

In a preferred embodiment of the proposal, it is provided that the support element is designed as a built-in steel part. During the production of the precast reinforced concrete part, the steel component is inserted into the formwork and mechanically connected to the other reinforcement elements of the precast reinforced concrete part in a suitable manner.

Furthermore, it is provided that the anchoring element is arranged in a connection area of the steel girder, which is located approximately in the middle of the steel girder. The length of the connection area is preferably about 10-25%, preferably about 12-20% of the length of the support element. The center of the steel beam (= central axis) is located in the connection area, with the connection area extending either symmetrically or asymmetrically around this central axis.

The invention also includes a precast reinforced concrete part with a longitudinal extension, with a support element as described above being arranged at least at one longitudinal end of the precast reinforced concrete part, which is held in the precast reinforced concrete part by concreted-in anchoring elements. The advantages described at the outset for the support element proposed according to the invention also relate in an analogous manner to a precast reinforced concrete part according to the invention which is equipped with such a support element.

The arrangement is selected in such a way that the support element protrudes laterally beyond the concreted area of the precast reinforced concrete part, but at least the underside of the steel beam protrudes from the precast reinforced concrete part (e.g. if the upper side is concreted over) in order to be able to place it on a supporting structure. The arrangement of the bearing plate ensures that after it has been placed on a support beam, the actual beam of the steel beam is at a distance from the support element and that the steel beam is completely protected against corrosion attacks and is embedded in the concrete and covered by overconcreting and underflow.

In an advantageous embodiment, it is provided that the anchoring element extends in a web of the precast reinforced concrete part. Prefabricated reinforced concrete parts according to the invention are often realized in a T-like section. The part that is vertically oriented in the installation situation is referred to as the web. With such a component, the advantages of the invention are fully apparent. Since the end anchoring of the anchoring element is precisely positioned on the steel girder of the support element due to the exact positioning of the anchoring element, thin webs of prestressed single or double T-girders can also be realized with the proposal according to the invention. The correct positioning of the anchoring element that is possible with the invention allows the invention to also be used in prefabricated reinforced concrete parts with narrow tension strand webs.

It is cleverly provided that the anchoring element only extends over part of the web height of the precast reinforced concrete part.

In this context, it is particularly pointed out that all the features and properties described in relation to the device, i.e. the support element or the precast reinforced concrete part, but also procedures, can also be transferred analogously to the formulation of the method according to the invention and can be used in the sense of the invention and are also disclosed. The same also applies in the opposite direction, which means that structural features that are only mentioned in relation to the production process, i.e. device-specific features, can also be taken into account and claimed within the scope of the device claims and are also part of the disclosure.

Fig. 1

eine Seitenansicht mit teilweiser Schnittdarstellung des erfindungsgemäßen Auflageelementes

Fig. 2

eine Frontansicht nach Fig. 1

Further features, details and advantages of the invention result from the wording of the claims and from the following description of exemplary embodiments with reference to the drawings. Show it:

1

a side view with a partial sectional view of the support element according to the invention

2

a front view 1

In the figures, elements that are the same or that correspond to one another are denoted by the same reference symbols and are therefore not described again unless this is expedient. The disclosures contained throughout the description can be transferred to the same parts with the same reference numbers or the same component designations. The position information selected in the description, such as top, bottom, side, etc., refers to the figure directly described and shown and must be transferred to the new position in the event of a change of position. Furthermore, individual features or combinations of features from the different exemplary embodiments shown and described can also represent independent, inventive solutions or solutions according to the invention.

In figure 1 the support element 1 according to the invention is shown. In the upper area (the selected view also corresponds to the arrangement in a typical application) is the steel beam 3, which is designed as profiled goods and has a longitudinal extent 32. According to the invention, the cross-sectional shape of the steel beam 3 is very variable, in figure 1 an I beam is known for this purpose, which has an upper chord 30 and a lower chord 31 .

At one end of steel beam 3, here in figure 1 at the left end, the steel girder 3 has a support area 40, via which the steel girder 3 and the prefabricated reinforced concrete part accommodating the steel girder 3 are supported on a supporting structure (not shown). In the support area 40, a support plate 41 is welded onto the underside of the steel girder 3, the bottom chord 31. The weld is marked as a short tack weld with 43. The support plate 41 is preferably welded diagonally to the lower chord 31 .

The steel girder 3 has a central axis 38 around which a connecting area 39 extends on both sides. In the direction of the longitudinal extension 32 of the steel girder 3, this connection area 39 has a length of approx. 10-35% of the total length of the support element 1 or the steel girder 3.

In the exemplary embodiment shown here, the central axis 38 coincides with the central axis 78 of the receiving element 7. In the exemplary embodiment shown here, the receiving element 7 is arranged as a sleeve together with the anchoring element 6 exactly in the middle of the steel girder 3.

In the exemplary embodiment shown here, the anchoring element 6 is designed as a reinforcing bar 62 or reinforcing steel and has a longitudinal extension that is described by the central axis 68 . The reinforcing bar 62 has on its lateral surface 64 a multiplicity of transverse or oblique ribs 63 which, as is customary in concrete construction, result in a bond with the concrete of the precast reinforced concrete part which is as form-fitting as possible.

One end of the reinforcing bar 62 projects into the sleeve 7 over a length 61 . The sleeve 7 is pressed onto the anchoring element 6 , here the rod 62 . The central axis 68 of the rebar 62 is aligned with the central axis 78 of the sleeve 7. This pressed area is in figure 1 characterized by the section 71 and is characterized by a reduced outer diameter compared to the section of the sleeve 7, which faces the steel beam 3.

The sleeve 7 is on the underside of the steel girder 3, here the bottom chord 31, welded. The weld seam, here a circumferential fillet seam, is marked with the reference number 36 .

The rebar 62 protrudes only partially into the sleeve 7, i.e. its insertion length 61 is less than the axial sleeve length of the sleeve 7. Therefore, between the end face 60 (or end face) of the rebar 62, which is inserted into the sleeve 7 , a free space 70 to the steel girder 3.

This free space 70 improves the overall quality of the weld. Since the reinforcing bar 62 does not protrude to the steel beam 3, less heat is dissipated during the welding and therefore the risk of compression deterioration and deformation and thus misalignment is also minimized at the same time. In the area of free space 70, there is also no compression, i.e. diameter reduction of sleeve 7, which benefits in particular the dimensional stability of sleeve 70 and its end facing steel girder 3, and facilitates the exact alignment of sleeve 7 in the welded joint by fillet weld 36.

For a mechanically stable press connection, it is favorable that the pressed-on section 71 of the sleeve 7, as shown here, is shorter than the insertion length 61 of the anchoring element 6, here the reinforcing bar 62. The pressed section 71 extends from that which faces away from the steel girder 3 end of the sleeve 7 in the direction of the steel beam 3.

The anchoring element 6, here the reinforcing rod 62, carries an end anchorage 8 at its end remote from the sleeve 7. This end anchorage 8 is designed, for example, as a hook, plate, anchor plate or washer. The end anchorage 8 is fastened in a variety of ways to the reinforcement rod 62 or the anchoring element 6, so that it can be subjected to mechanical loads in a stable manner. In figure 1 and 2, for example, a weld with a fillet weld 80 is shown. However, it is also possible to provide a mechanical forming process for fixing the end anchorage 8 on the anchoring element 6 . This includes, for example, upsetting or bending over of the end area of the anchoring element 6. It is also possible to connect the end anchoring by friction welding or flash butt welding.

The invention is not limited to one of the embodiments described above, but can be modified in many ways.

All of the features and advantages resulting from the claims, the description and the drawing, including structural details, spatial arrangements and method steps, can be essential to the invention both on their own and in a wide variety of combinations.

Reference List

1

support element

3

steel beam

6

anchoring element

7

receiving element / sleeve

8th

end anchorage

30

upper belt

31

bottom chord

32

longitudinal extent

36

Weld / fillet weld

38

central axis

39

connection area

40

support area

41

support plate

43

Weld

60

end face

61

Standing or insertion length

62

Reinforcing bar / rebar

63

Rod with ribs / ribs

64

lateral surface

68

central axis

70

free space

71

Pressed or clamped area

78

central axis

80

fillet weld

Claims (16)

1. Supporting element for a precast reinforced concrete part, which has a steel girder (3) with a bearing area (40) or a bearing plate (41) and the steel girder (3) is integrally connected to a receiving element (7) which is one of the steel girder (3) protruding anchoring element (6), characterized in that the receiving element (7) is pressed onto the anchoring element (6). 2. Support element according to claim 1, characterized in that the receiving element (7) is a sleeve. 2. Support element according to claim 1, characterized in that the receiving element (7) is welded (36) to the steel girder (3). 3. Support element according to one of the preceding claims, characterized in that between the end surface (60) of the in the receiving element (7) protruding anchoring element (6) and the steel beam (3) there is a free space (70). 4. Support element according to one of the preceding claims, characterized in that the pressed-on section (71) of the receiving element (7) is the same length or shorter than the standing length (61) of the anchoring element (6) in which the receiving element (7). 5. Support element according to one of the preceding claims, characterized in that the anchoring element (6) is designed as a bar (62), in particular as a reinforcing bar or as a bar with ribs (63) on the lateral surface (64). 6. Supporting element according to one of the preceding claims, characterized in that the anchoring element (6) has an end anchorage (8) at its end remote from the receiving element (7). 7. Support element according to one of the preceding claims, characterized in that the steel girder (3) has an upper chord (30) and a lower chord (31) and the anchoring element (6) on the lower chord (31) preferably projects at right angles. 8. Support element according to one of the preceding claims, characterized in that the steel beam (3) as a profile product, in particular as an I; T-; Double-; U-; Double U or rectangular profile is formed. 9. Support element according to one of the preceding claims, characterized in that the anchoring element (6) is arranged in a connection region (39) of the steel girder (3) which is located approximately in the center of the steel girder (3). 10. Supporting element according to one of the preceding claims, characterized in that the length of the connecting region (39) comprises approximately 10 to 25%, preferably approximately 12 to 20% of the length of the supporting element (1). 11. Precast reinforced concrete part with a longitudinal extension, wherein a support element according to one of the preceding claims is arranged at least at one longitudinal end of the precast reinforced concrete part, which is held in the precast reinforced concrete part by concreted-in anchoring elements (6). 12. Precast reinforced concrete part according to claim 11, characterized in that the anchoring element (6) extends in a web of the precast reinforced concrete part. 13. Precast reinforced concrete part according to one of the preceding claims 11 to 12, characterized in that the anchoring element (6) extends over only part of the web height of the precast reinforced concrete part. 14. A method for producing a support element, in particular according to one of claims 1 to 10, as a steel component of a precast reinforced concrete part, characterized by the following steps: - Pressing a receiving element onto an anchoring element; - integral connection of the receiving element with the steel support of the support element. 15. The method according to claim 14, characterized in that the receiving element is pushed onto the anchoring element in such a way that a free space (70) remains in the receiving element over the end surface of the anchoring element.

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