EP2893083A1

EP2893083A1 - In situ concrete safety barrier

Info

Publication number: EP2893083A1
Application number: EP13783463.6A
Authority: EP
Inventors: Alexander Barnas; Thomas Edl
Original assignee: Kirchdorfer Fertigteilholding GmbH
Current assignee: Kirchdorfer Fertigteilholding GmbH
Priority date: 2012-09-10
Filing date: 2013-09-10
Publication date: 2015-07-15
Anticipated expiration: 2033-09-10
Also published as: PL2893083T3; EP2893083B1; AT512411A4; ES2620399T3; AT512411B1; WO2014036580A1

Abstract

The invention relates to an in situ concrete safety barrier (1) comprising an in situ concrete body (2) provided with an essentially continuous reinforcement (5), at least one groove (4) extending essentially perpendicular to the longitudinal extension of the in situ concrete safety barrier (1) is arranged on a surface (3) of the in situ concrete body (2). According to the invention, at least one reinforcement reinforcing part (6) is arranged in the in situ concrete body (2) in the region of the at least one groove (4).

Description

ORTBETONSCHUTZWAND

The invention relates to a Ortbetonschutzwand according to the preamble of claim 1.

Ortbetonschutzwände be used as a vehicle restraint system, which are intended to prevent vehicles from accidentally leaving a roadway, and thus to keep the vulnerability of the occupants low. An in-situ concrete protective wall is here a concrete wall, which is manufactured on site. Such Ortbetonschutzwände are usually by means of a

Sliding shell method produced, which can be made in a simple process long continuous in-situ concrete walls. To one

Breaking the Ortbetonschutzwand to prevent, are such

Ortbetonschutzwände provided with a continuous reinforcement. At the

Curing the concrete of the in-situ concrete protection wall and in consequence of

Temperature expansions usually form cracks. Such cracks can in this case propagate over the entire surface and can in this case a

unpredictable and therefore particularly dangerous weakening of the

Represent in situ concrete protective wall. In order to prevent an uncontrolled spread of these cracks, these Ortbetonschutzwände may have grooves, wherein the crack propagation is stopped when hitting the groove, or there may be no uncontrolled formation of cracks, as the

Ortbetonschutzwand only at the cross-sectional weakening, ie in the grooves, tears.

The disadvantage of this is that these grooves represent a cross-sectional constriction and in a collision case of a vehicle in the region of such a groove, the risk of vehicle breakdown or concrete chipping is increased.

The object of the invention is therefore to provide a Ortbetonschutzwand of the type mentioned, with which the mentioned disadvantages can be avoided, with which the risk of vehicle breakdown or concrete chipping in the region of the grooves can be kept low.

This is achieved by the features of claim 1 according to the invention. This results in the advantage that the risk of a concrete spalling can be reduced, since any force effects in the groove over a larger space to be distributed. As a result, furthermore, the risk of injury to the vehicle occupants in the event of a vehicle collision can be kept low. Furthermore, the danger of a vehicle breakthrough by the in-situ concrete protective wall in the region of the groove can be kept low by the additional reinforcement reinforcement part. By positioning the reinforcing reinforcement parts only in the region of the groove Ortbetonschutzwand can further be made economically, as a complex and costly continuous

Additional reinforcement can be dispensed with. In particular, by the

Transport costs and the use of materials of reinforcing reinforcing parts are kept low.

Furthermore, the invention relates to a method for producing a

Ortbetonschutzwand according to claim 8.

The object of this method is to produce the advantageous in-situ concrete protective wall in a quick and economical manner.

This is achieved by the features of claim 8 according to the invention.

Thereby, the advantageous in-situ concrete protective wall can be easily and reliably manufactured with the at least one reinforcement reinforcement part.

The subclaims relate to further advantageous embodiments of the invention.

It is hereby expressly referred to the wording of the claims, whereby the claims at this point are incorporated by reference into the description and are considered to be reproduced verbatim.

The invention will be described in more detail with reference to the accompanying drawings, in which only preferred embodiments are shown by way of example. Showing:

Fig. 1 shows a first preferred embodiment of an in-situ concrete protection wall in axonometric representation;

FIG. 2 shows the in-situ concrete protective wall according to FIG. 1 as a section through the groove; FIG.

3 shows a second preferred embodiment of an in-situ concrete protection wall in FIG Side view;

4 shows a first preferred embodiment of a reinforcing reinforcement part in axonometric representation;

Fig. 5 of the reinforcing reinforcement part of Figure 4 in elevation.

6 shows a second preferred embodiment of a reinforcement reinforcement part in axonometric representation;

FIG. 7 shows the reinforcing reinforcement part according to FIG. 6 in elevation; FIG.

8 shows a third preferred embodiment of a reinforcing reinforcement part in axonometric representation; and

Fig. 9, the reinforcing reinforcement part of FIG. 8 in elevation.

FIGS. 1 to 3 show preferred embodiments of an in-situ concrete protective wall 1 comprising an in-situ concrete body 2 provided with a substantially continuous reinforcement 5. An in-situ concrete protective wall 1 can be used here

in particular be part of a vehicle restraint system. such

Ortbetonschutzwände 1 are preferably placed next to roadways to prevent a deal of a vehicle from the road. For this purpose, in particular the longitudinal extension of the in-situ concrete protective wall 1 parallel to

Longitudinal extension of the adjacent roadway be arranged. To avoid damage to impacting vehicles and in particular a rollover of the impacting vehicle can be provided in particular that the

Ortbetonkörper 2 has a New Jersey profile. An in-situ concrete protective wall 1 has an in-situ concrete body 2, which can be produced, in particular, at the planned site of use. An in-situ concrete body 2 can in this case be produced in particular by means of a sliding shell method. Furthermore, the

Ortbetonschutzwand 1 in particular a continuous Ortbetonkörper 2 have.

The in-situ concrete body 2 is provided with a substantially continuous reinforcement 5 Mistake. The reinforcement 5 is intended to absorb the tensile forces occurring in the event of an impact and thus to prevent a breakdown of a vehicle. This reinforcement 5 can in particular one or more

Have reinforcing elements 9, which may be formed for example as a traction cable and / or as reinforcing bars. Essentially continuous in this sense means that the reinforcement 5 does not necessarily have to consist of a continuous reinforcing element 9, but that several, itself

in particular overapplying reinforcing elements 9, can be provided.

On a surface 3 of the in-situ concrete body 2, at least one groove 4 runs essentially normal to the longitudinal extension of the in-situ concrete protective wall 1. This groove 4 serves to prevent uncontrolled crack propagation on the surface 3 of the in-situ concrete body

Ortbetonkörpers 2 to prevent the curing of the Ortbetonkörpers 2. According to the preferred embodiments in FIGS. 1 to 3, provision can be made in particular for the groove-in the operating position of the in-situ concrete body 2-to extend from one longitudinal side over the upper side to the opposite longitudinal side. In other words, that the groove 4 extends over an entire circumference of the surface 3 of the Ortbetonkörpers 2, but without its footprint. But it can also be provided that the groove 4 has a shorter length, for example, that the groove 4 extends only over a longitudinal side. It can also be provided that the groove 4 extends over an entire circumference of the surface 3. The groove 4 may in particular have a depth between 3 cm and 5 cm.

It is provided that in the region of the at least one groove 4 at least one

Reinforcing reinforcement part 6 is arranged in the Ortbetonkörper 2. The at least one reinforcing reinforcement part 6 can be arranged in particular in the region of the at least one groove 4 in the in-situ concrete body 2, in particular for reinforcing the in-situ concrete protective wall 1 in the region of the at least one groove 4. In other words, the reinforcing reinforcement part 6 is a local, ie in particular non-continuous, additional reinforcement which additionally reinforces the in-situ concrete body 2 in the region of the groove 4. Of the

Reinforcing reinforcement part 6 may be formed in particular of metal, particularly preferably of reinforcing steel. Particularly preferably, the

Reinforcement reinforcement part 6 formed of at least partially galvanized steel be. As a result, the reinforcing reinforcement part 6 can be arranged close to the surface of the in-situ concrete body 2.

This results in the advantage that the risk of concrete spalling can be reduced since any force effects in the region of the groove 4 are distributed over a larger space. As a result, furthermore, the risk of injury to the vehicle occupants in the event of a vehicle collision can be kept low. Furthermore, the risk of a vehicle breakthrough by the in-situ concrete protection wall 1 in the region of the groove 4 can be kept low by the additional reinforcement reinforcement part 6. By positioning the reinforcement reinforcement parts 6 only in the region of the groove 4, the in-situ concrete protection wall 1 can further

be formed economically, as can be dispensed with a complex and costly continuous additional reinforcement. In particular, thereby the transport cost and the use of material of

Reinforcement reinforcing parts 6 are kept low.

In particular, it can be provided that the in-situ concrete body 2 has a plurality of grooves 4, wherein in particular the grooves 4 can be arranged at substantially constant distances from each other. In particular, it may be envisaged that the substantially constant distance between two grooves 4 is between 3 m and 15 m.

Furthermore, it can be provided that at least one reinforcing reinforcement part 6 is provided per groove 4 substantially. This can in particular

be provided that the extent of at least one

Reinforcement reinforcement part 6 parallel to the longitudinal extent of

Ortbetonschutzwand 1 less than half, in particular less than a quarter, the distances between two adjacent grooves 4 is. Particularly preferably, it can be provided that the at least one reinforcing reinforcement part 6 is between 0.5 m and 1.5 m long. As a result, the Ortbetonwand to at least 50%, in particular at least 75%, of the longitudinal extension without

Reinforcement reinforcement member 6 may be formed, whereby the material used for the reinforcing reinforcement parts 6 can be kept low.

The first preferred embodiment of an in-situ concrete protection wall 1 in Fig. 1 and Fig. 2, as well as the second preferred embodiment of an in-situ concrete protection wall 1 in Fig. 3 each have 4 reinforcing elements 9. In Fig. 1 and Fig. 3, some of the concealed by the Ortbetonkörper 2 reinforcing elements 9 and reinforcing reinforcing member 6 are shown by dashed lines.

In particular, it can be provided that a reinforcement reinforcement part 6 is arranged in regions substantially around a reinforcement element 9 around.

According to the first preferred embodiment of an in-situ concrete protection wall 1, it can be provided that in the region of the groove 4 only one

Reinforcing reinforcement part 6 is arranged, which is arranged in particular around the uppermost reinforcing element 9.

According to the second preferred embodiment of an in-situ concrete protection wall 1, it can be provided that around or at each reinforcement element 9 a

Reinforcing reinforcement part 6 is arranged.

Particularly preferably, it can be provided that the at least one

Reinforcement reinforcement part 6 is attached to the reinforcement 5. This attachment can be done in different ways, for example by clamping,

Welding, riveting, screwing, tying and / or deforming to give a non-exhaustive list. By attaching the at least one reinforcement reinforcement part 6 to the substantially continuous reinforcement 5, tensile forces in the region of the groove 4 can be distributed over a larger area. Furthermore, the manufacture of the in-situ concrete protective wall 1 can thereby be simplified, since the at least one reinforcing reinforcement part 6 can be fixed to the reinforcement 5.

Alternatively, it can be provided that the at least one

Reinforcing reinforcement part 6 is formed self-standing, or on the

Reinforcement 5 is only put on.

Particularly preferably, it can be provided that the reinforcing reinforcement part 6 has a marking 7, which marking 7 reaches at least as far as the surface 3 of the in-situ concrete body 2. The mark 7 can in this case in particular as Extension be formed. The marking 7 may in particular be formed as a part of the at least one reinforcing reinforcement part 6, which extends at least as far as the surface 3 of the in-situ concrete body 2, while the remaining reinforcing reinforcement part 6 is arranged in the in-situ concrete body 2. The fact that the marking 7 extends at least as far as the surface 3 of the in-situ concrete body 2 means, in particular, that the marking 7 is visible from the outside, either because the marking 7 directly adjoins the surface 3 or beyond the surface 3. This can be done from the outside in a simple way

be determined where the Ortbetonkörper 2 of the at least one

Reinforcement reinforcement part 6 is reinforced, and therefore where the grooves 4 are to be introduced.

Furthermore, it can be provided that the at least one

Reinforcing reinforcement member 6 is integrally formed, so that the mark 7 and the remaining reinforcing reinforcement member in one piece, and in particular of the same material, are.

Alternatively it can be provided that the reinforcing reinforcement part 6

multi-piece, in particular two-piece, is formed, in particular the marking 7 of a different material than the rest

Reinforcing reinforcement part 6 may be formed. Since the mark 7

preferably has no forces to absorb, the mark 7 may be formed of light and / or economic materials such as plastic, wood and / or cardboard, the mark 7 on the rest

Reinforcement reinforcement member 6 may be attached. This allows the

Reinforcement reinforcement member 6 may be simpler and lighter, in particular reinforcing steel can be saved.

According to the second preferred embodiment of an in-situ concrete protection wall 1, provision can be made, in particular, for only one reinforcement reinforcement part 6 to have a marking 7 per groove 4.

In particular, it can be provided that the at least one groove 4 is arranged at a predetermined distance from the marking 7. For example, the groove 4 may be arranged immediately adjacent to the marking 7. This can be special preferably take place when the mark 7, as shown for example in the preferred embodiments of a reinforcing reinforcing member 6 in Fig. 4 to Fig. 9, is arranged centrally.

Furthermore, it can be provided that the groove 4 extends directly over the marking 7, wherein in particular parts of the marking can be removed in the formation of the groove 4.

According to an embodiment, not shown, it may also be provided that the marking 7 is arranged eccentrically on the reinforcing reinforcement part 6, in particular on the edge of the reinforcing reinforcement part 6. Here, the groove 4 can be introduced at a predetermined distance to the mark 7, wherein this predetermined distance, in particular the distance of the mark to the center of the reinforcing reinforcement part 6 is. Thereby, the mark 7, which does not absorb any forces, spaced from the groove 4 are arranged, whereby no additional weakening of the Ortbetonkörpers 2 in the region of the groove 4 takes place by the marking 7.

The reinforcing reinforcement part 6 may be formed as a substantially one-dimensional body, for example as a longitudinal bar. As a substantially one-dimensional body in this case, in particular a body can be considered, which extends in a Cartesian axis much further than in the other two Cartesian axes. A trained as a rod

Reinforcing reinforcement part 6 can then be fastened to the reinforcement 5.

Furthermore, it can be provided that the reinforcing reinforcement part 6 as in

Essentially two-dimensional body, for example as a plate is formed. As a substantially two-dimensional body can be considered here a body which extends in two Cartesian axes much further than in the third Cartesian axis. A reinforcement reinforcement part 6 designed as a plate can then be fastened to the reinforcement 5. Furthermore, a reinforcing reinforcement part 6 designed as a plate can have perforations.

Particularly preferably, it can be provided that the reinforcing reinforcement part 6 as a three-dimensional body, for example as a cuboid or as helical body, is formed. As a three-dimensional body can be considered in this sense, in particular a body whose longest

Longitudinal extent in a Cartesian axis which can be up to ten times the other two longitudinal extents in the other Cartesian axes. This three-dimensional body can in particular have at least one opening through which the in-situ concrete body 2 can engage in the reinforcing reinforcement part 6. A trained as a three-dimensional body

Reinforcing reinforcement part 6 may for example be milled from a body, or be formed by a curved plate. Such a trained reinforcing reinforcing member 6 offers in contrast to a rod or

plate-shaped reinforcing reinforcement member 6 has the advantage that the

Ortbetonkörper 2 in a much larger space of the

Reinforcing reinforcement part 6 can be reinforced.

According to the preferred embodiments of reinforcement reinforcement parts 6 illustrated in FIGS. 4 to 9, it can be particularly preferred that the at least one reinforcing reinforcement part 6 comprises at least one rod 8, in particular a plurality of rods 8, and that the at least one rod 8 has a three-dimensional body, in particular a reinforcing cage, forms and / or is part of the three-dimensional body. Here, the diameter of the at least one rod 8 may be substantially smaller than the dimensions of the three-dimensional body. For better clarity, not all rods 8 are provided with a reference numeral in FIGS. 4, 6 and 8. Such a

For example, three-dimensional bodies may be formed by a plurality of rods 8 connected together. However, the reinforcement reinforcement part 6 can also be formed only by a bent rod 8. By using at least one rod 8 for forming the three-dimensional body, this body may have a plurality of large apertures through which the Ortbetonkörper 2 can pass. As a result, a particularly lightweight and easily formed reinforcing reinforcement part 6 can be formed, which can reinforce a large space of the in-situ concrete body 2.

According to the first preferred embodiment of a reinforcing reinforcement part 6 in FIGS. 4 and 5, the reinforcing reinforcement part 6 can be referred to as Reinforcing cage be formed. For this purpose, in particular a plurality, in particular four, straight rods 8 may be provided, which are arranged parallel to the reinforcement 5, in particular to the reinforcement element 9, wherein a plurality of bent rods 8 are arranged on the straight bars 8. The bent rods 8 can in this case be bent into a closed line, for example a ring or the circumference of a polygon, in particular a square.

According to FIG. 5 it can be provided that the first preferred embodiment of a reinforcing reinforcing bar 6 is arranged around a reinforcing element 9, wherein the reinforcing element 9 of the reinforcement 5 can be arranged within a surface which is surrounded by the curved bars. Here, the reinforcing reinforcement parts 6 can be pushed onto the individual reinforcing elements 9 and then secured.

According to the second preferred embodiment of a

Reinforcing reinforcement part 6 in Fig. 6 and Fig. 7 may be provided that the reinforcing reinforcement member 6 has a receptacle 10 for placing on the reinforcement 5, in particular on a reinforcing element 9. For this purpose, the bent rods can in particular form an inwardly directed loop, which loop is provided for receiving the reinforcement 8. As a result, the reinforcing reinforcement part 6 can subsequently be simply placed on a reinforcement 5. This requires an additional attachment of the

Reinforcement reinforcing parts 6 on the reinforcement 5 not to be made, or may be particularly simple.

According to the third preferred embodiment of a

Reinforcing reinforcement part 6 in FIG. 8 and FIG

Reinforcing reinforcement part 6 only comprise a bent rod 8, which is bent substantially in a helical line. This helix may in particular be connected at the ends to the reinforcement 5. This third preferred embodiment of a reinforcing reinforcing member 6 is particularly easy to manufacture and can also be retrofitted to a finished

continuous reinforcement 5 are attached. Furthermore, such a reinforcement reinforcement part 6 offers the advantage that this in one

Sliding cup method is particularly easy to introduce into the Ortbetonkörper 2. In order to avoid splintering of the Ortbetonkörpers 2 in the region of the groove 4 particularly well can be provided in particular that the at least one groove 4 in the Ortbetonkörper 2 a core cross-section transverse to the longitudinal extent of

Ortbetonschutzwand 1 limited, and that the at least one

Reinforcing reinforcement part 6 is arranged at least partially outside the core cross-section. The core cross section is in this case that continuous cross section of the in-situ concrete body 2, which is free of interruptions. The core cross-section corresponds to the hatched area in FIG. 2. As a result, the groove engages in the at least one reinforcing reinforcement part 6, as a result of which the at least one reinforcing reinforcement part 6 can be arranged particularly close to the surface. Furthermore, the at least one reinforcing reinforcement part 6 can additionally reinforce the parts of the in-situ concrete body 2 which are exposed through the groove 4 particularly well. It can also be provided that the at least one groove 4 is cut into the at least one reinforcing reinforcement part 6.

A method for producing an in-situ concrete protective wall 1, in particular the in-situ concrete protective wall 1 described above, will be described below.

For this purpose, a substantially continuous reinforcement 5 is arranged, wherein in the region of the reinforcement 5 at least one reinforcing reinforcement part 6 is arranged. Here, in particular, the reinforcement 5 can be arranged at the point where the Ortbetonschutzwand 1 is to be produced.

Furthermore, it is provided that in a concreting process, the reinforcement 5 and the at least one reinforcing reinforcement part 6 is enveloped to form an in-situ concrete body 2. The concreting process can in particular by means of a

Gleitschalenverfahren done.

It is further envisaged that after a given degree of cure of the

Ortbetonkörpers 2 in the region of at least one reinforcing reinforcement part 6 at least one groove 4 is introduced into a surface 3 of the Ortbetonkörpers 2. The predetermined degree of hardening may in this case preferably be a degree of hardening of the concrete of the in-situ concrete body 2, in which the in-situ concrete body 2 is statically stable in such a way that it retains a shape without external action, but has not yet completely hardened. As a result, an advantageous in-situ concrete protective wall 1 can be easily manufactured.

In this case, it may in particular be provided that a plurality of

Reinforcing reinforcing members 6 are arranged on the reinforcement, and that the reinforcing reinforcement members 6, in particular at regular intervals, in particular at intervals of 3 m to 15 m, from each other. As a result, several grooves can be arranged at regular intervals.

Particularly preferably, it may be provided that: ^■ before concreting - a reinforcement reinforcing member is fixed to the reinforcement 5 6 at least. As a result, forces can be transmitted to the at least one reinforcing reinforcement part 6 better to the reinforcement 5. Furthermore, the risk can be substantially avoided ervorganges a displacement of the at least one reinforcement reinforcing member 6 during the Betom ^'.

Furthermore, it can be provided that the groove 4 is introduced by a machining process in the surface 3 of the Ortbetonkörpers 2. As a result, the grooves 4 can be introduced into the surface 3 of the in-situ concrete body 2 in a particularly simple manner.

Particularly preferably, it can be provided that the at least one groove 4 is introduced at a predeterminable distance to the marking 7 of the reinforcing reinforcement part 6 reaching at least as far as the surface 3 of the in-situ concrete body 2. By this mark 7 can be determined in a simple manner even after the concreting, where the Ortbetonkörper 2 by the at least one

Reinforcement reinforcement part 6 is reinforced, and in this area targeted the groove 4 are introduced. As a result, even in the event that the at least one reinforcing reinforcement part 6 has moved during the concreting process, the groove in the area of the at least one reinforcing reinforcement part 6 can be reliably secured

be introduced.

If the position of the at least one reinforcing reinforcing part 6 is known, it can be provided that by determining the position, in particular from one end of the in-situ concrete protective wall 1, with the at least one Reinforcing reinforcement part 6 provided region of the Ortbetonkörpers 2 can be determined. This determination of the position can be done for example in a simple way by means of a tape measure. This can be advantageous, in particular for relatively short cast-in-place protective walls 1, since the outlay for determining the position of the at least one reinforcing reinforcement part 6 can be kept low.

Furthermore, it can be provided that after the concreting step the area provided with the at least one reinforcing reinforcement part 6

Ortbetonkörpers 2 are determined by means of a detector. This detector may be, for example, a metal detector or an ultrasonic measuring device. It can also be provided that the at least one reinforcing reinforcement part 6 is provided with a FID chip, and that a suitable receiving device is used as the detector. This can also be dispensed with the application of the mark.

In a sliding shell method, in particular, a sliding shell paver can be used, which comprises a front shield, through which shield the continuous reinforcement 5 is guided during the concreting process.

In particular, it can be provided that in a sliding shell process as concreting at least one helical

Reinforcement reinforcement member 6 is introduced through an opening, in particular through a hole in a front plate of a slip shell paver in the Ortbetonkörper 2. Here, the helical

Reinforcement reinforcement part 6 particularly easy by the movement of the

Sliding tray paver along the longitudinal extension of the in-situ concrete protective wall 1 are continuously introduced through the opening in the shield in the Ortbetonkörper, whereby the manufacturing process is substantially simplified.

Claims

PATENT APPLICATIONS

1 . Ortbetonschutzwand (1) comprising a, with a substantially continuous reinforcement (5) provided Ortbetonkörper (2), wherein on a surface (3) of the Ortbetonkörpers (2) at least one groove (4) substantially normal to the longitudinal extent of the Ortbetonschutzwand (1 ), characterized in that in the region of the at least one groove (4) at least one reinforcing reinforcement part (6) in the Ortbetonkörper (2) is arranged.

2. Ortbetonschutzwand (1) according to claim 1, characterized in that the at least one reinforcing reinforcement part (6) on the reinforcement (5) is attached.

3. Ortbetonschutzwand (1) according to claim 1 or 2, characterized

in that the reinforcing reinforcement part (6) has a marking (7) which marking (7) at least up to the surface (3) of the

In-situ concrete body (2) is sufficient.

4. Ortbetonschutzwand (1) according to 3, characterized in that the marking 7 is formed as an extension.

5. Ortbetonschutzwand (1) according to claim 3 or 4, characterized

characterized in that the at least one groove (4) is arranged at a predetermined distance from the marking (7).

6. Ortbetonschutzwand (1) according to one of claims 1 to 5, characterized in that the at least one reinforcing reinforcement part (6) at least one rod (8), in particular a plurality of rods (8), comprises, and that the at least one rod ( 8) forms a three-dimensional body, in particular a reinforcing cage, and / or forms part of the three-dimensional body.

7. Ortbetonschutzwand (1) according to one of claims 1 to 5, characterized in that the at least one groove (4) in the Ortbetonkörper (2) defines a core cross-section transverse to the longitudinal extension of the Ortbetonschutzwand (1), and that the at least one reinforcing reinforcement part (6 ) is arranged at least partially outside the core cross-section.

8. A method for producing an in-situ concrete protective wall (1), in particular an in-situ concrete protective wall (1) according to one of claims 1 to 7, wherein a substantially continuous reinforcement (5) is arranged, wherein in the region of the reinforcement (5) at least one reinforcing reinforcement part (6 ), wherein in a concreting process, the reinforcement (5) and the at least one

Reinforcement reinforcement part (6) is enveloped to form an in-situ concrete body (2), wherein after a predetermined degree of cure of the in-situ concrete body (2) in the region of the at least one reinforcing reinforcement part (6) at least one groove (4) into a surface (3) of the in-situ concrete body (2) is introduced.

9. The method according to claim 8, characterized in that - before the concreting - the at least one reinforcing reinforcement part (6) to the reinforcement (5) is attached.

10. The method according to claim 8 or 9, characterized in that the groove (4) by a machining process in the surface (3) of the

Ortbetonkörpers (2) is introduced.

1 1. A method according to any one of claims 8 to 10, characterized

in that the at least one groove (4) is introduced at a predeterminable distance to a marking (7) of the reinforcing reinforcement part (6) reaching at least to the surface (3) of the in-situ concrete body (2).

12. The method according to any one of claims 8 to 11, characterized

characterized in that in a sliding shell process as concreting at least one helical reinforcement reinforcement part (6) through an opening, in particular through a hole, in a front plate of a slip shell paver in the Ortbetonkörper (2) is introduced.