CH714770B1 - Retaining wall element and retaining wall made of retaining wall elements. - Google Patents

Abstract

In a retaining wall element (1) comprising a wall body (10) with a visible side (12) and a supporting side (11), at least one anchor box (32) arranged in the wall body (10) and accessible from the visible side is provided according to the invention. The anchor socket (32) is connected to the support side (11) via at least one continuous horizontal anchor opening (35) for passing through an associated horizontal anchor (50) and the anchor socket (32) has at least one bearing surface (34) for fastening the associated horizontal anchor (50) on.

Description

TECHNICAL AREA

The invention relates to a retaining wall element for erecting a retaining wall, the retaining wall element comprising a wall body with a supporting side. The invention further relates to a retaining wall that is constructed from such retaining wall elements and to a connection module for such a retaining wall.

BACKGROUND OF THE INVENTION

The CH676015 describes a retaining wall construction for securing backfilling with a wall forming an outer skin made of a plurality of horizontally and vertically lined up prefabricated elements. Wall piles protrude through openings in the prefabricated elements, which are connected to injection support piles via coupling sockets. The prefab elements rest on supports screwed onto the lower sections of the wall piles. In order to secure the support piles against lateral migration, soil nails are provided which are fastened to the circumference of the coupling sleeve and protrude into the adjacent soil at different angles. The prefabricated elements are profile stones cast from concrete with through-holes for the wall piles arranged symmetrically to their vertical center plane. In the horizontal direction, the prefabricated elements are connected by means of a tongue and groove connection. The remaining cavities of the prefabricated elements are filled with concrete after the wall has been built, which can, however, lead to uneven finishes on the top of the wall, which could cause problems with the desired resistance to freeze-thaw salt.

Another disadvantage of this retaining wall construction is that it is complex and therefore rather expensive to build, especially because many individual profile blocks must be pushed over previously attached support and wall piles and stacked on top of each other. It is necessary that the support piles are first driven into the ground at precisely defined positions. In addition, due to the relatively weak anchoring of ground pegs, the support structure cannot absorb any large transverse loads - also because these act on the coupling sleeves below the wall. So-called earth reinforcements are used to absorb higher transverse loads, but this is not possible in many cases.

[0004] A retaining wall construction is known from CH684102, which is also anchored in the ground with vertically driven-in injection piles. To absorb the transverse loads, it also has injection piles driven in at an angle at different angles. Reinforcing irons are fastened between the ends of the vertical injection piles protruding from the ground. The free ends of the oblique grouting piles are connected to the vertical grouting piles. The actual retaining wall made of concrete is then created in a known manner using formwork, in that the ends of the injection piles and the reinforcing iron are cast in concrete. Here, too, erecting the support structure on site is time-consuming and therefore expensive.

Another known system, like the retaining wall construction from CH676015, has several profile blocks made of concrete. In contrast to the retaining wall construction from CH676015, the transverse anchors, e.g. pegs, are attached to the wall posts using steel cables, e.g. by folding them over. To attach the steel cables, a notch is punched into the respective profile stone. In this case, too, the construction of the retaining wall is time-consuming and costly. Due to the centrally arranged passage openings for the wall piles, which are later completely concreted, the finished retaining walls are 25 cm thick or more, which can also lead to increased material costs, especially for concrete.

The CH707671 of the same applicant shows a retaining wall element with a wall body having a support side on which at least one cantilevered connection element for an anchor rod is attached. The projecting connection element has at least one continuous anchor opening for passing through and fastening the respective anchor rod. In comparison to the systems mentioned above, such retaining wall elements allow retaining walls to be erected easily, quickly and inexpensively. Particularly in the case of relatively high retaining walls and, for example, in the case of difficult geological subsoil to be supported, additional anchoring in the subsoil may also be necessary when using such retaining wall elements, which makes the construction of a retaining wall more difficult.

PRESENTATION OF THE INVENTION

One object of the present invention is to specify a retaining wall element or a retaining wall that enables retaining walls to be built quickly and cost-effectively, even if the material to be supported is difficult (e.g. geological subsoil such as loose soil and rock). In order to be able to erect a retaining wall from several retaining wall elements in a stable and safe manner in the long term under such framework conditions, the use of ground or rock anchors that are essentially horizontal, i.e. perpendicular to the supporting sides of at least individual retaining wall elements (or the wall body of these retaining wall elements), is proposed. Such horizontal anchors can in particular be rod anchors and/or stranded anchors, with the use of other types of anchors being possible. In particular, self-drilling anchors or injection anchors can be used, which allow self-drilling installation while simultaneously using the anchor rod as a drill rod with a lost drill bit. After the self-drilling anchors have been drilled into the ground, they can be injected by injecting an injection agent or Injection mortar to be anchored in the subsoil. It is also possible to use drill anchors that are known per se and are drilled in casing. For example, pre-injected anchor rods are inserted into the drill pipe, which are then completely surrounded by the injection mortar underground.

Especially with difficult geological subsoil, the problem often arises in practice that certain areas of the subsoil are not suitable for the insertion of an anchor. On the one hand, lines such as electrical lines or water pipes and seepage lines can be present in the subsoil to be supported, which must be avoided when horizontal anchors are installed. Furthermore, the subsoil to be supported can also have an inhomogeneous geological structure in which, for example, certain horizontally deposited layers do not allow mechanically sufficient anchoring even when using anchors with injection mortar and should therefore be avoided when positioning a horizontal anchor. As a result, in such situations, horizontal anchors cannot be used, or only with great effort, in the retaining walls made from retaining wall elements known from the prior art. In particular, a complex pre- and / or post-processing of the retaining wall elements and special anchor heads is necessary in order not to critically influence the mechanical integrity of the retaining wall element and still obtain a permanently resilient force transmission between a horizontal anchor introduced into the ground and the retaining wall element.

It is an object of the present invention to solve at least one of the aforementioned problems.

A retaining wall element according to the invention comprises a wall body with a support side and a visible side and at least one anchor box which is accessible from the visible side and is arranged in the wall body. According to the invention, the anchor socket is connected to the support side by means of at least one continuous horizontal anchor opening for the passage of an associated horizontal anchor. The anchor socket has at least one bearing surface for fastening the associated horizontal anchor. For certain applications, several horizontal anchors can be used and fastened in the same anchor socket. An anchor socket can also be arranged at least partially on the visible side of the wall body, i.e. protrude at least partially from the visible side. Good results can be obtained if the body of the wall is at least partly made of reinforced concrete.

The so-trained inventive retaining wall elements can be used in many ways. For example, they can be used to secure buildings, such as traffic routes, especially on slopes, or for garden walls or to secure the banks of water bodies, e.g. against flooding.

For certain applications, a retaining wall element according to the invention can also have several such anchor sockets with horizontal anchor openings, which can be arranged in a certain way in the wall body.

A mechanically advantageous transmission of force between the horizontal anchor and the wall body can be achieved if the at least one bearing surface is set up to accommodate a bearing plate. As a result, a mechanically advantageous transmission of force between the horizontal anchor and the retaining wall element can be achieved in a relatively simple manner, as will be explained further below. According to one embodiment, an anchor box can also have a number of bearing surfaces, for example two bearing surfaces which are separated from one another by the horizontal anchor opening.

In an embodiment of a retaining wall element suitable for certain applications, the anchor socket has a socket volume for receiving a securing element (e.g. a spherical collar and/or hexagon nut) for the associated horizontal anchor. With such an embodiment of a retaining wall element, an anchor head used to connect the horizontal anchor can be easily protected from weather-related damage after the connection has been made, for example by closing the anchor socket with a cover on the visible side of the wall body. Alternatively or in addition, the anchor socket can be at least partially filled with a filling material (e.g. an injection mortar or a polymer) after the horizontal anchor has been connected.

A particularly inexpensive to produce embodiment of a retaining wall element can be achieved if the anchor box and the horizontal anchor opening are at least partially formed by an anchor bush, as will be explained in more detail below in connection with the figures included. Such an anchor head can be made, for example, at least partially from sheet metal or from a plastic. An anchor head made of plastic can be produced in particular by means of an injection molding process.

An embodiment with a particularly high mechanical strength and rigidity can be achieved if the wall body has a bulge surrounding the horizontal anchor opening on the supporting side, or if the total thickness of the wall body in the area of the horizontal anchor opening is increased compared to the average thickness of the rest of the wall body is. In this way, the stress distribution in the wall body caused by a horizontal anchor can be improved, as will be explained in more detail below in connection with the illustrations. A retaining wall element that is particularly resilient mechanically can be achieved if it essentially consists of reinforced concrete and the reinforcement in the area of the bulge is arranged in such a way that forces introduced by a horizontal anchor are distributed from the bulge into the surrounding wall body.

In certain embodiments of a retaining wall element according to the invention, such a bulge is at least partially delimited by at least one frame element surrounding the horizontal anchor opening. Such a frame element enables in particular a simpler and thus more cost-effective production of retaining wall elements with bulges.

In order to improve the internal stress distribution in certain load cases acting on a retaining wall element, the at least one frame element can be at least partially embedded in the wall body, as will be explained in more detail below.

In order to simplify the production of a retaining wall element with a bulge, such a frame element can be mechanically operatively connected via at least one web to the at least one anchor socket and/or the at least one horizontal anchor opening (or the anchor socket partially delimiting this). In particular, the frame element, the anchor box and/or the horizontal anchor box can be designed in one piece.

In order to achieve a relatively high degree of freedom with regard to the orientation of a horizontal anchor within a preferred angular range relative to the supporting side of the wall body and at the same time to be able to guarantee good structural-mechanical properties, according to one embodiment of the invention, when the retaining wall element is in the assembled state, the at least one horizontal anchor opening can be provided with a Angle of inclination from 0 to 20 degrees to the horizontal of the wall body. Alternatively or in addition to this, when the retaining wall element is in the installed state, the horizontal anchor opening can have a greater extent in the vertical direction than in the horizontal direction.

In order to be able to safely arrange several retaining wall elements next to one another for the construction of a retaining wall, a preferred embodiment of a retaining wall element can have lateral connecting means for connecting two adjacent retaining wall elements. Such connecting means can include lateral connecting openings which, for example, cause a mechanical connection between adjacent retaining wall elements by means of steel bolts arranged therein.

A particularly stable retaining wall, which can also be built quickly and inexpensively at the same time, is possible with an embodiment of a retaining wall element according to the invention, in which at least one cantilevered connection element for a vertical anchor is provided on the support side of the wall body, each of which has at least one continuous vertical anchor opening for carrying out and fastening the respective vertical anchor, as will be shown in more detail in the following detailed description of the embodiments shown in the figures. The continuous vertical anchor opening can be at least partially formed by a duct (e.g. a corrugated duct, or spiro tube) in order to improve the transmission of forces between an inserted vertical anchor and the retaining wall element. A retaining wall element that can withstand particularly high mechanical loads can be achieved if the at least one cantilevered connection element of the retaining wall element is manufactured in one piece with the remaining wall body from reinforced concrete.

A retaining wall element with a cantilevered connection element, which can be produced particularly easily and has a high mechanical integrity, can be achieved if the at least one cantilevered connection element of the retaining wall element has a connection module of the type as will be described in more detail below. A particularly high level of mechanical integrity can be achieved if such a connection module, as described here, comprises at least one reinforcement which, starting from a socket wall of the connection module, extends into the wall body. For certain types of retaining wall elements, the at least one reinforcement can also be operatively connected to a reinforcement arranged in the wall body. For certain load cases acting on a retaining wall element, the connection socket of a connection module can be arranged at least partially in the wall body. Such embodiments can be particularly advantageous if particularly high forces are to be transmitted to vertical anchors in certain embodiments of retaining wall elements.

The present invention also relates to a retaining wall made up of several retaining wall elements arranged next to one another in the longitudinal direction, as described herein, with horizontal anchors each having one end fastened in an anchor head. The horizontal anchor is preferably a drill rod of a self-drilling anchor and is fixed in the subsoil by means of injection mortar. At least individual horizontal anchors of such a retaining wall can be fixed at least partially in the horizontal anchor opening by means of injection mortar.

The invention also discloses a retaining wall module comprising a retaining wall element as described here and further comprising a bearing plate, the bearing plate being designed in such a way that when the retaining wall module is in the assembled state, the bearing plate rests on the bearing surface and at the same time at least partially closes the horizontal anchor opening towards the anchor socket . Good results can be achieved if the bearing plate has a curved bearing surface, the curvature of which at least partially corresponds to the curvature of a securing element for the horizontal anchor.

The invention further relates to a connection module for connecting a ground anchor and/or rock anchor to a retaining wall element, which is ideally suited for use with a retaining wall element as described here. Such a connection module according to the invention normally has a connection socket, comprising a socket wall with a socket base adjoining it. The can wall and the can bottom surround a filling space that is accessible via a pouring opening. At least one first sleeve tube is arranged in the filling space for receiving a ground anchor and/or a rock anchor, which connects a bottom opening arranged in the can bottom with the pouring opening. Particularly good results can be achieved if the can wall and the can bottom are made of sheet steel. These can, for example, be operatively connected to one another via welded joints and/or soldered joints. Particularly stable connection modules can be achieved if the can wall and/or the can base is made at least partially from sheet steel with a thickness of between 2 and 10 mm (millimeters), in particular with a thickness of approximately 5 mm.

In order to obtain a mechanically particularly advantageous connection to a wall body of a retaining wall element, the connection module can have at least one reinforcement which extends uninterruptedly from an outside of the connection module through a first reinforcement opening arranged in the bush wall into the filling space. The reinforcement can be, for example, reinforcing steel. In order to obtain retaining wall elements with particularly good mechanical integrity, several reinforcements configured as described herein can be included.

For certain applications that require advantageous force transmission between a wall body and a ground and/or rock anchor, the at least one reinforcement can extend from the first reinforcement opening via the filling space to a second reinforcement opening arranged in the wall of the box and through the second reinforcement opening extend to the outside of the connection module. For such an embodiment, a one-piece reinforcement can be produced, e.g. from a possibly bent reinforcing steel.

A connection module that enables a particularly advantageous power transmission from a ground or rock anchor arranged in the first cladding tube into a retaining wall element can be achieved if the at least one reinforcement in the filling space encircles the cladding tube at least partially. For this purpose, the at least one reinforcement can, for example, loop around the cladding tube or be bent into a U-shape. In one embodiment of the invention, the at least one reinforcement touches the cladding tube in at least one load area and/or in a load area that is a maximum of 10 mm (millimeters) away from the cladding tube.

At least one second cladding tube can be arranged in the filling space. Such a can also connect a bottom opening arranged in the can bottom with the pouring opening, like the first cladding tube. Alternatively, a second cladding tube can connect a first wall opening arranged in the can wall to a second wall opening arranged in the can wall. Such a second cladding tube can also serve to accommodate a ground or ground anchor and/or be used to connect retaining wall elements arranged next to one another.

The filling space of a connection module according to the invention can be at least partially filled with mortar or concrete. Backfilling with other building materials is possible. When using a connection module for a retaining wall element, in particular at least partial filling with a building material that is identical to the building material of the wall body is possible. However, by using a connection box according to the invention, the filling space can also be at least partially filled with a building material that differs from the building material of the wall body. According to the invention, for example, the use of a concrete or mortar with special mechanical or chemical properties (e.g. high mechanical strength) in the filling space is conceivable, whereas for the wall body, for example, a more economical standard concrete or mortar can be used.

In a variation of a retaining wall element according to the invention, the wall body comprises at least one hollow wall element, the hollow wall element having a first shell arranged towards the support side and a second shell arranged essentially parallel and at a distance from the first shell and towards the visible side. Such an embodiment can be advantageous for certain applications, since it has a relatively low weight compared to other embodiments due to the hollow wall elements (in the still hollow state). The first and the second shell of a cavity wall element normally define at least one volume that can be filled with a filling material (e.g. concrete, in particular in-situ concrete). Such a hollow wall element can be configured in such a way that the volume or space between the two shells can be filled with in-situ concrete after assembly at the place of use, as a result of which a structure with high mechanical load-bearing capacity can be created. Thus, such retaining wall elements can be assembled relatively easily (i.e. e.g. with common standard construction machines), or even very large retaining wall elements can still be assembled without the mandatory use of heavy-duty cranes or excavators.

Good results can be obtained when the outward facing side of the first shell forms at least part of the support face and the outward facing face of the second shell forms at least part of the visible face. Particularly stable embodiments can be achieved if the first and/or the second shell consist at least partially of concrete. In particular, the shells can comprise concrete provided with reinforcements/reinforcements. Alternatively or in addition, the first and/or the second shell can also consist at least partially of metal or wood or plastic. The use of other materials is possible. A retaining wall element that can withstand particularly high mechanical loads can be achieved if the first and the second shell are connected to a reinforcement which preferably also serves as a spacer for the two plates. Particularly good results can be achieved if the first and the second shell are connected to lattice girders, which form a reinforcement when the cavity wall element is in the filled state. According to a variation of the invention, the first and/or the second shell is substantially flat. In a further variation, at least a part of the first and/or the second shell has a curvature and/or a kink. A retaining wall element with a partially increased wall thickness can thus be created in a simple manner, as a result of which special load cases can be successfully countered.

A retaining wall element that allows a particularly simple erection of retaining walls that can withstand particularly high mechanical loads can be achieved if the wall body has at least one transverse force connection device arranged on an end face of the wall body for transverse force connection of the retaining wall element to a second retaining wall element, as will be shown in more detail below. These shear force connection devices can also be used for shear force connection of the retaining wall element with other types of components. According to a preferred variation of such a retaining wall element, the shear force connection device comprises a shear force mandrel bearing for receiving a shear force mandrel (or sliding mandrel). In this way, transverse forces between individual retaining wall elements can be transmitted particularly efficiently and displacements due to temperature fluctuations can be adequately compensated.

The invention therefore also relates to a retaining wall element comprising a wall body and at least one connection module according to the present description, the filling space being at least partially filled with a first building material and the wall body being essentially made of a second building material that differs from the first building material

The connection box of a connection module can be arranged on the surface of a cantilevered connection element of a retaining wall element. However, the junction box can also be at least partially surrounded by an outer protective layer (e.g. bitumen, foil) and/or at least partially embedded in another building material, e.g. in concrete or mortar.

BRIEF EXPLANATION OF THE FIGURES

Aspects of the invention are explained in more detail on the basis of the exemplary embodiments shown in the following figures and the associated description. They show in each case schematically: FIG. 1 a first retaining wall element with inserted horizontal anchor in a first perspective view; FIG. 2 shows the retaining wall element from FIG. 1 in a second perspective view; FIG. 3a shows an embodiment of an anchor head in a perspective view; FIG. 3b shows the anchor bushing from FIG. 3 with hidden edges shown; FIG. FIG. 4 shows the retaining wall element from FIG. 1 with the wall body partially removed for illustrative exposure of the embedded anchor head in a perspective view; Fig. 5 detail D from Fig. 4; 6 shows a second retaining wall element with inserted horizontal anchor in a perspective view; Fig. 7 Detail E from Fig. 6; 8 shows a third retaining wall element with inserted horizontal anchor in a perspective view; Fig. 9 section A-A of Fig. 8; Fig. 10 Detail F from Fig. 9; 11 shows a first retaining wall comprising retaining wall elements in a perspective view; 12 shows a second retaining wall comprising retaining wall elements in a perspective view; 13 shows an embodiment according to the invention of a connection module with several reinforcements in a perspective view; FIG. 14 shows the connection module from FIG. 13, with hidden edges being shown as dashed lines; FIG. 15 shows a retaining wall element with two connection modules according to the embodiments shown in FIGS. 13 and 14, with one connection module being cut open for illustrative reasons; Fig. 16 detail G from Fig. 15; 17 shows a further embodiment of a retaining wall element according to the invention in a perspective view; Fig. 18 Detail H from Fig. 17.

WAYS TO CARRY OUT THE INVENTION

In the following figures and the associated description, the corresponding parts are provided with the same reference numbers unless otherwise noted. The exemplary embodiments described are each exemplary of the subject matter of the invention and have no restrictive effect.

1 and 2 show a first embodiment of a retaining wall element 1 according to the invention. The retaining wall element 1 has a panel-shaped wall body 10 which essentially consists of reinforced concrete. The wall body 10 has a support side 11 which, in the assembled state, is directed towards the subsoil (rock or soil) to be supported by a retaining wall to be produced. The retaining wall 1 also includes an anchor socket 32 which is accessible from the visible side 12 and is also arranged in the wall body 10 . The anchor socket 32 is connected to the support side 11 by means of a continuous horizontal anchor opening 35 . A horizontal anchor 50 can be passed through this horizontal anchor opening 35, as shown in the figures. Such a horizontal anchor 50 can be, for example, a drill rod of a self-drilling anchor. The anchor socket 32 and the horizontal anchor socket 35 are formed in part by an anchor socket 30 made from sheet metal, of the kind shown somewhat in Figures 3a and 3b below. On the supporting side 11 of the wall body 10 there is also a bulge 15 which surrounds the horizontal anchor opening 35 and serves, among other things, to reinforce the retaining wall element 1 . The bulge 15 is partly formed by a frame element 31, which, among other things, simplifies the manufacture of such a retaining wall element 1.

The horizontal anchor opening 35 of the retaining wall element shown in FIGS. 1 and 2 has a greater extent in the vertical direction than in the horizontal direction, as a result of which a horizontal anchor 50 can be driven in different directions (schematically by the broken double arrow) into the underlying subsoil. In this way, for example, a line (not shown) located behind it can be avoided or, for example, reinforcements of an already existing structure can be avoided.

In addition, the embodiment of a retaining wall element 1 according to the invention shown in FIG. 1 and FIG. The projecting connection elements 20 are preferably made in one piece with the remaining wall body 10 from reinforced concrete. The two projecting connection elements 20 are each aligned with the lower edge of the wall body 10. In this way they form a kind of foot which facilitates the vertical positioning of the retaining wall element 1. The two cantilevered connection elements 20 are also offset inwards by about 2 to 5 cm in relation to the lateral edge of the wall body 10 . The wall body 10 has a height of about one meter and a width of about three meters and is about 20 cm thick. The projecting connection elements 20 are essentially rectangular and protrude from the supporting side 11 of the wall body 10 by approximately 50 to 80 cm, preferably approximately 70 cm. The cantilevered connection elements 20 have a height of about 40 cm to 70 cm, preferably about 60 cm, and are offset below the upper edge of the wall body, so that they would be completely covered by any road surface or by heaped up soil or the like and Vertical anchor 40 would not protrude beyond the top of the wall body 10.

The projecting connecting elements 20 each have a vertical anchor opening 21 for fastening vertical anchors 40 . Different types of vertical anchor openings 21 are provided, a first type being designed for essentially vertical vertical anchor rods 40 and a second type for vertical anchors 40 deviating somewhat from the vertical. The vertical anchor openings 21 shown have an angle of inclination of about 5 degrees, so that the two vertical anchors 40 can be driven into the ground at a slight angle forwards, i.e. towards the visible side 12 of the wall body 10 . The vertical anchor openings 21 are preferably formed from metal sheathing corrugated pipes cast into the projecting connection elements 20, such as are used, for example, in prestressed concrete buildings.

3a and 3b show an embodiment of an anchor bushing 30, such as is present in the embodiment of a retaining wall element 1 shown in FIGS. The embodiment shown of an anchor head 30 essentially consists of sheet metal. The anchor head 30 comprises an anchor socket 32 which delimits a socket volume 33 which is used in particular to accommodate an anchor attachment (not shown). At the end of the box volume directed toward the support side 11 of the wall body 10, the anchor box 30 has two bearing surfaces 34 for fastening a horizontal anchor (not shown) fed through the horizontal anchor opening 35. The anchor bushing 30 is designed in such a way that the horizontal anchor opening 35 defined by it has a greater extent in the vertical direction (z-direction) than in the horizontal direction (y-direction) in order, when the anchor bushing 30 is in the installed state, to accommodate a horizontal anchor in different angular orientations within a to be able to introduce it into the anchor box 32 in a vertical plane (xz plane) standing normally on a supporting side of the corresponding wall body. The anchor head 30 shown also includes a frame element 31 which, in the mounted state, surrounds the resulting horizontal anchor opening 35 and (as shown in e.g. FIG. 2) can delimit a bulge 15 in the wall body 10. The frame element 31 is mechanically operatively connected to the anchor socket 32 or the horizontal anchor opening 35 via a plurality of webs 36 .

As shown schematically in FIG. 4 and FIG. 5, the anchor box 32 can be covered or closed by means of a cover 37 (partially cut off for better illustration). In this way, an essentially level visible side 12 can be achieved. Likewise, if required, the anchor socket 32 can be opened, for example for the purpose of periodic inspection of the anchoring.

As also illustrated in FIG. 4 and FIG. 5, in the anchor box 32 there is a bearing surface 34 which is divided into two by the horizontal anchor opening 35 and on which a bearing plate 53 can be mounted. The support plate 53 in the embodiment shown is designed as a shim. Such a relatively simply designed anchor head can be used, for example, for short-sided securing during the construction of a wall from a plurality of retaining wall elements 1.

A particularly good transmission of force between the horizontal anchor 50 and the retaining wall element 1 can be achieved, for example, via an embodiment as shown in FIG. 6 and FIG. The horizontal anchor opening 35 has a greater extent in the vertical direction (z-direction) than in the horizontal direction (y-direction), resulting in a relatively large two-part bearing surface (not directly visible in the figures) as in the embodiment of FIG. A bearing plate 53 arranged in the anchor socket 32 rests on these bearing surfaces. The bearing plate has a recess with a curved bearing surface 54, in which a spherical collar nut 51 is mounted and thus a horizontal anchor 50 can be connected to the retaining wall element 1 as shown. Additional security is provided, for example, by using a hexagon nut 52 as a security element. As shown schematically in Fig. 6 by the double arrow with the dashed line, such an embodiment of the invention allows a high degree of freedom when aligning a horizontal anchor 50 within a vertical plane (xz plane) that is essentially perpendicular to the support side 11, which means that anchoring can also be carried out in difficult Underground becomes possible because known obstacles such as lines can be avoided. As shown schematically by the double arrow with a dotted line, the expansion of the horizontal opening 35 can be selected in such a way that a certain degree of freedom in aligning the horizontal anchor 50 in the horizontal plane (xy plane) is also obtained.

8, 9 and 10 show a further embodiment of a retaining wall element 1 according to the invention, in which in the assembled state the horizontal anchor opening 35 is inclined at an angle of inclination α of 15 degrees to the horizontal (xy plane) of the wall body 10. In this way, a high degree of freedom in aligning the supplied horizontal anchors 50 in a specific angular range relative to the horizontal (xy plane) can be achieved without the structural integrity of the retaining wall element 1 being significantly reduced. Such embodiments of a retaining wall element 1 can be offered, for example, in standardized sets with different angles of inclination and/or can be manufactured specifically for the application with a predetermined angle of inclination.

10 also shows schematically the flow of forces in the retaining wall element 1 in the area of the anchor socket 32. The bulge 15 arranged on the support side 11 of the wall body 10 results in the horizontal anchor 50 via the spherical collar nut 51 and the bearing plate 53 via the bearing surface 34 in the Supporting wall element 1 introduced forces in a spatially well distributed stress field. In this way, the forces acting on the support side 11 can be spatially distributed over a relatively large volume to the horizontal anchor 50 without the wall body 10 being subjected to supercritical local loads. The embodiment of a retaining wall element 1 shown also has a frame element 31 made of sheet metal, which surrounds and delimits the bulge 15 . On the one hand, the frame element 31 simplifies the production of the retaining wall element 1 since it can serve as part of the mold for the concrete casting of the retaining wall element 1 . On the other hand, for certain applications, the frame element 31 can also be at least partially embedded in the frame body, as shown in FIG. In this way, the flow of forces within the wall body 10 can be influenced and, for example, mechanical damage to the wall body 10 in the transition area between the bulge 15 and the wall body 10 that is not bulged can be prevented.

11 shows an embodiment of a retaining wall 80 formed from a plurality of retaining wall elements 1 joined together. The retaining wall 80 comprises a lower row of retaining wall elements 1 of a first embodiment arranged next to one another in the longitudinal direction. In this first embodiment, the vertical anchors 40 are each inclined forward at an angle of inclination to the vertical (z-axis). In the vertical direction (z-axis) above these retaining wall elements 1 there is a second upper row of retaining wall elements 1 of a second embodiment arranged next to one another in the longitudinal direction. In this second embodiment, the vertical anchors 40 are each inclined backwards at an angle of inclination to the vertical (z-axis). In addition, in the retaining wall 80 shown, all retaining wall elements 1 have horizontal anchors 50 which anchor the retaining wall elements 1 in the subsurface (not shown) adjoining the supporting side 11 . The retaining wall elements according to the invention make it possible to guide the horizontal anchors 50 into the subsoil in alignments adapted to both the statics of the wall and the nature of the subsoil to be supported, and thus, for example, to be able to avoid cables located in the subsoil.

12 shows a further embodiment of a retaining wall 80 which is formed from retaining wall elements 1 according to the invention. The retaining wall 80 comprises a plurality of retaining wall elements 1 arranged next to one another, each of which has a platform 70 aligned with the upper edge of the wall body 10 . The retaining wall elements 1 comprise projecting connection elements 20 in which vertical anchor openings 21 are arranged. Further vertical anchor openings 21 are arranged in the platforms 70 in such a way that when a first retaining wall element 1 is placed on the platform of a second retaining wall element, the vertical anchor openings 21 in the cantilevered connecting elements 20 of the first retaining wall element 1 so into the vertical anchor openings 21 of the platform 70 of the second retaining wall element 1 aligned so that the first and the second retaining wall element can be mechanically connected to one another by means of a connecting means 60 (e.g. a bolt) arranged in the vertical anchor openings 21 . The embodiment of a retaining wall element 1 shown in FIG. 12 also has lateral connection openings 22 arranged in the cantilevered connection elements 20, whereby retaining wall elements 1 arranged laterally next to one another can also be mechanically connected to one another by means of connection means 60. Larger retaining walls 80 can also be erected quickly and easily in this way, since due to the high degree of freedom in aligning the horizontal anchors 50 with the retaining wall elements 1 according to the invention, each of the retaining wall elements 1 can be anchored both horizontally and vertically if required.

A retaining wall according to the invention can also comprise at least individual retaining wall elements which are not retaining wall elements according to the invention as described here.

13 and 14 show an embodiment of a connection module 100 according to the invention, which can be used to connect a ground anchor and/or rock anchor (not shown) to a retaining wall element (not shown). The connection module 100 comprises a connection socket 110 which has a socket wall 111 with a socket bottom 112 adjoining it. The socket wall 111 and the socket base 112 are made of welded sheet steel and surround a filling space 120 which is accessible via a pouring opening 113 and which can be filled with mortar, for example. In the filling space 120 of the embodiment shown, a first envelope tube 130 is attached, which connects a bottom opening 125 arranged in the can bottom 112 to the pouring opening 113 . The cladding tube 130 is welded to the edge of the bottom opening 125 so that the filling space 120 can be filled with an at least temporarily liquid building material, if required, without this being able to penetrate into the cladding tube 130 or escape through the bottom opening 125 . The connection module 100 also includes four reinforcements 140 made of reinforcing steel, which are distributed along the longitudinal axis (parallel to the z-axis) of the cladding tube 130 . The reinforcements 140 each have an essentially U-shape and each extend from the outside of the connection module 100 through a first reinforcement opening 114 arranged in the sleeve wall 111 into the filling space 120, where they run around the cladding tube 130 and then by means of a second reinforcement opening 115 can be guided through the bushing wall 111 to the outside of the connection module 100 again. As shown schematically, the reinforcements 140 protrude outwards from the can wall 111, so that they can be integrated, for example, into the structure of an adjoining wall body, as will be shown below with reference to FIGS. 15 and 16. The reinforcements 140 are arranged in the filling space 120 in such a way that they touch the cladding tube 130 at a number of points forming load areas 141 .

15 and 16 show an embodiment of a retaining wall element 1 with two projecting connection elements 20, which each have an embodiment of a connection module 100 according to the invention. As shown schematically, the filling space 120 is filled with a mortar in which four reinforcements 140 are enclosed. The reinforcements extend through the sleeve wall 111 into the wall body 10 of the retaining wall element 1. A sheath tube 130 arranged in the filling space 120 forms a vertical anchor opening 21 in which a vertical anchor 40 can be arranged as shown.

17 and 18 show a further embodiment of a retaining wall element 1 in which the wall body 10 is a cavity wall element 16. The cavity wall element 16 has a first shell 17 positioned towards the support side 11, of which the upper corner positioned on the left-hand side in the figures has been cut away (shown schematically with dotted lines) for purely illustrative purposes. It also has a second shell 18 which is arranged essentially parallel and at a distance from the first shell 17 and the visible side 12 . The first and second shells 17, 18 define a volume 19 that can be filled with concrete. The first and second shells 17, 18 of the embodiment shown consist of reinforced concrete and are mechanically connected to one another by means of corrugated reinforcements 140 acting as spacers. The retaining wall element 1 shown also has transverse force connection devices 90 arranged on a first and a second end face 13, 14 of the wall body 10, which can be used for the transverse force connection of the retaining wall element 1 with further retaining wall elements (not shown) or other components adjoining the end faces 13, 14. The transverse force connecting devices 19 contained in the embodiment shown are transverse force mandrels 91 mounted in transverse force mandrel bearings 92, or sliding mandrels.

LIST OF REFERENCE MARKS

1 Retaining wall element 10 Wall body 11 Support side 12 Visible side 13 First face 14 Second face 15 Bulge 16 Cavity wall element 17 First shell 18 Second shell 19 Volume 20 Projecting connection element 21 Vertical anchor opening 22 Lateral connection openings 30 Anchor head 31 Frame element 32 Anchor socket 33 Socket volume 34 Bearing surface 35 Horizontal anchor opening 36 Web 37 cover 40 vertical anchor 50 horizontal anchor 51 domed collar nut 52 securing element 53 bearing plate (anchor plate) 54 bearing surface (spherical) 60 connecting means 70 platform 80 retaining wall 90 shear force connection device 91 shear force mandrel 92 shear force mandrel bearing 100 connection module 110 connection bush 111 bush wall 112 bush bottom 113 pouring opening 114 first reinforcement opening backfill space 125 floor opening 130 first cladding tube 140 reinforcement (reinforcement) 141 load area 99 wall opening α angle of inclination

Claims (20)

1. Retaining wall element (1), comprising a wall body (10) with a supporting side (11) and a visible side (12) and at least one anchor socket (32) arranged in the wall body (10) and accessible from the visible side (12), the anchor socket ( 32) is connected to the support side (11) via at least one continuous horizontal anchor opening (35) for passing through an associated horizontal anchor (50) and the anchor socket (32) has at least one bearing surface (34) for fastening the associated horizontal anchor (50). 2. Retaining wall element (1) according to claim 1, characterized in that the at least one bearing surface (34) is designed to receive a bearing plate (53). 3. Retaining wall element (1) according to one of the preceding claims, characterized in that the at least one anchor box (32) has a box volume (33) for receiving a securing element (52) for the associated horizontal anchor (50). Retaining wall element (1) according to any one of the preceding claims, characterized in that the anchor box (32) and the horizontal anchor hole (35) are formed by an anchor box (30). Retaining wall element (1) according to claim 4, characterized in that the anchor head (30) is at least partially made of sheet metal or plastic. 6. Retaining wall element (1) according to one of the preceding claims, characterized in that the wall body (10) on the supporting side (11) has a bulge (15) surrounding the horizontal anchor opening (35). Retaining wall element (1) according to claim 6, characterized in that the bulge (15) is delimited at least partially by at least one frame element (31) surrounding the horizontal anchor opening (35). 8. Retaining wall element (1) according to one of the preceding claims, characterized in that when the retaining wall element (1) is in the assembled state, the at least one horizontal anchor opening (35) is inclined at an angle of inclination (α) of 0 to 20 degrees to the horizontal of the wall body (10). . 9. Retaining wall element (1) according to one of the preceding claims, characterized in that when the retaining wall element (1) is in the assembled state, the horizontal anchor opening (35) has a greater extent in the vertical direction than in the horizontal direction. Retaining wall element (1) according to any one of the preceding claims, characterized in that it comprises lateral connecting means (22) for connecting two adjacent retaining wall elements (1). 11. Retaining wall element (1) according to one of the preceding claims, characterized in that at least one projecting connection element (20) for a vertical anchor (40) is provided on the supporting side (11) of the wall body (10), which in each case has at least one continuous vertical anchor opening (21 ) for carrying out and fastening the respective vertical anchor (40). 12. Retaining wall element (1) according to one of the preceding claims, characterized in that the wall body (10) comprises at least one hollow wall element (16), the hollow wall element (16) having a first shell (17) arranged towards the supporting side (11) and an im The second shell (18) is arranged substantially parallel to and at a distance from the first shell (17) and the visible side (12). 13. Retaining wall element (1) according to one of the preceding claims, characterized in that the wall body (10) has at least one transverse force connection device (90) arranged on an end face (13, 14) of the wall body (10) for transverse force connection of the retaining wall element (1) to a second Retaining wall element (1). 14. Retaining wall element (1) according to claim 13, characterized in that the transverse force connection device (19) has a transverse force mandrel bearing (92) for receiving a transverse force mandrel (91). 15. Retaining wall (80) made up of a plurality of retaining wall elements (1) arranged next to one another in the longitudinal direction according to one of claims 4 to 14, wherein horizontal anchors (50) are each fastened with one end in a respective anchor head (30). 16. Connection module (100) for connecting a ground anchor and/or rock anchor (40, 50) to a retaining wall element (1) according to one of claims 1 to 14 a. comprising a junction box (110). b. a can wall (111) with a can bottom (112) adjoining it, wherein c. the can wall (111) and the can bottom (112) surround a filling space (120) accessible via a pouring opening (113), wherein i.e. at least one first sleeve tube (130) for receiving a ground anchor and/or rock anchor is arranged in the filling space (120) and via which a bottom opening (125) arranged in the can bottom (112) is connected to the pouring opening (113). 17. Connection module (100) according to claim 16, characterized in that the connection module (110) has at least one reinforcement (140) which extends without interruption from an outside of the connection module (100) through a first reinforcement opening (114 ) extends through into the filling space (120). 18. Connection module (100) according to claim 17, characterized in that the at least one reinforcement (140) extends from the first reinforcement opening (114) via the filling space (120) to a second reinforcement opening (115) arranged in the can wall (111) and extends through the second armouring opening (115) to the outside of the connection module (100). 19. Retaining wall element (1) according to claim 11, characterized in that the at least one cantilevered connection element (20) of the retaining wall element (1) has a connection module (100) according to one of claims 16 to 18. 20. Retaining wall element (1) according to claim 11, characterized in that the at least one projecting connection element (20) of the retaining wall element (1) has a connection module (100) according to one of claims 17 to 18 and the at least one reinforcement (140) of the connection module (100) extending from the socket wall (111) into the wall body (10).