DE19800011A1 - Cell structure, in particular slope retaining wall or room dividing wall - Google Patents

Abstract

Species of the invention: cellular structure, in particular a retaining system or a space dividing wall, comprising a fore-part (VB) and a backfill (HF) which is connected to said fore-part by interlocking or friction. The fore-part (VB) comprises solid supporting units (TE), preferably of trough- or box-like shape, arranged in the lateral and vertical direction in the front part of the structure. Task of the invention: to provide a cellular structure of enhanced connection stability. Features of the invention for solution: there is provided at least one coupling unit (KE), preferably a plurality thereof which are stiff, in particular as a whole, or have stiff sections. Said coupling unit is connected to said fore-part (VB) by interlocking or friction and extends therefrom into the depth of said backfill (BF). Further, said coupling unit is connected or provided with at least one anchoring unit (WDE) located in said backfill (HF).

Description

The invention relates to a cell structure, in particular as Slope retaining wall or partition wall that has a porch and includes a backfill. The latter is in with the stem Form and / or non-positive connection, the stem in Ver area of the building front in the side and height direction divides arranged solid support elements, which before are preferably formed like a trough or box and in are generally made of concrete. This support element form a cell division of the front by their arrangement construction and thus also with the inside of it Related area of the backfill. One reason The function of the combination of stem and backfill is Ensuring a predetermined stability against tipping moments due to the horizontal component of the in the rear filling weight pressure, insofar as this is the local Shear or sliding strength of the filling material exceeds. That of the construction, especially of weight, weight distribution and foot thickness, depending on the stem strength and supportability of the considered for itself In this context, baues has a useful effect, however the price of a substantial effort, which is basically should be kept as low as possible. In the present Connection is therefore only on the stability of the Composite of stem and backfill so that especially the widely used constructions with stems without substantial self-support against tipping moments are included in the subject matter of the invention.

The main influencing variable is thus the one by the so-called "Slope angle" marked, usually by purpose moderate material selection and compaction to increase slip resistance within the backfill. In the following one is sufficient high shear strength between the foundation surface on the one hand  as well as stem and filling material on the other hand be so that a sliding structure is not considered as a whole is coming. Then are within the considered rear only those parts that are above or above in front of the under the Slope angle towards the rear of the sliding interface lie. Those below or behind this interface Areas, on the other hand, are not only independent, but have even increasing with distance from the interface Support ability.

This partial support ability can help support the slip endangered filling parts are used, by means of flexible tension elements such as ropes, wires or flat material lanes, possibly in connection with voluminous anchoring elements. The flexible traction elements need to be their Realize function within the filling under preload but can only be applied when the Filling material can be inserted behind the stem. This has the Disadvantage that the construction progress and especially when a defined compression of the filling material in layers Position and an at least approximately predetermined bias of the flexible elements is no longer guaranteed. Through the Resilience of the anchoring can also maintain its shape of the structure with regard to settling in the area of the filling or in the background. Known Constructions with up to the grown background of the Building-led rock anchors and the like have in this Context out of consideration.

The object of the invention is therefore first to create a Cell structure that is characterized by improved bond strength and dimensional stability. The solution according to the invention this task is determined by the features of claim I. With such a construction there is a defined spatial Arrangement between the also generally made of concrete  existing coupling elements and the associated support elements given and also during the introduction and compaction of the Backfill guaranteed. This is mainly due to little Very rigid in sections, but in particular overall rigid and not only tensile in the direction of anchoring, but also achieved pressure-resistant coupling elements KE, the form and non-positive, essentially also pull and pressure firmly connected to the support elements TE of the stem. A high level of stability of the building is in this together hang in the depth of the extension of the coupling elements Backfill HF reached, where generally not only with one high consolidation, but even with a layer behind or can be calculated below the sliding interface. All in all is besides the solution of the special invention task also achieved a more balanced distribution of forces in the network. The mutual securing of the position of the support elements and coupling elements also facilitates particularly intensive compaction in the different layers of the backfill, so that overall a higher slope angle and a steeper position of the the sliding interface, d. H. an enlargement of the support capable volume part of the backfill.

A preferred embodiment of the invention provides that a plurality of coupling elements one in a rear, have solidified area of the backfilling leading length and that associated abutment elements in the intensely solidified and supportable backfill area are arranged. The offers significant progress in terms of stability of the structure even under difficult geological conditions nits.

According to an essential development of the invention at least one coupling element, but preferably a plurality the same, at least in sections itself as in the rear filling arranged abutment elements with correspondingly effective Pressure receiving areas for the transmission of anchoring forces  intended. This often leads to a somewhat more complicated one Design and manufacture of the combined coupling and contr bearing elements in concrete technology, but results in an some applications highly desired, further increase the bond strength and dimensional stability of the structure. Furthermore shapes itself with the backfilling and compression Progressive assembly of the concrete skeleton easier and work saving.

The latter applies in particular to further training in Invention, according to which at least one connection between one Coupling element on the one hand and a supporting element of the stem and / or an anchoring element on the other hand by a preferably in the vertical direction hookable teeth forms is. This enables a particularly quick and easy producible but also reliable positive connection, especially if, according to a preferred variant Interlocking due to backfill pressure acting from above are held in a positive connection.

An important and independent, but especially in Kombina tion with other features of the invention and with all mentioned Advantages of further training are that each Pairs of at different heights within the stem neighboring supporting elements by at a distance from the building front Shear bars arranged in the backfill against the horizon tale relative displacement are positively secured to each other. This construction method means that the is transmitted to a supporting element in the direction from the backfill to the building frontal horizontal forces on one building at a time Floor lower support element or several of the same. This makes this horizontal load acting in the tilting direction down inside the structure, d. H. towards the filling areas located below the sliding interface who have their own support capacity.  

In this way there is a substantial increase in Stability and long-term stability of the structure. The shift of forces can thus over a plurality of buildings floors are effective, if necessary up to the foundation level, with which a practically complete safety against tipping over can be achieved. To do this, however, it is appropriate to transfer the power between the individual floors take effect relatively far back to let d. H. as close as possible or beyond the border Sliding surface. This will be achieved through further development achievable according to the invention, the shear bar a Interlocking connection with up or down neigh beard anchoring elements or with in the corresponding Have end regions of the coupling elements. These elements or According to the invention, element areas are anyway wide in the back of the filling, d. H. at least near the sliding Interface and also in preferably highly compressed Filling areas.

Other features and advantages of the invention are set out below Reference to those shown schematically in the drawings Exemplary embodiments explained. Herein shows:

Fig. 1 shows a first embodiment of a cell structure according to the invention for supporting a slope, shortened in height shown with only three floors, in a vertical cross-section,

Fig. 2 a similar sectional view for the foot portion of a second embodiment of a fiction, modern cellular structure to support slope, according to the section plane II-II in Fig. 3,

Fig. 3 shows a partial horizontal section of the cellular structure of Fig. 2 according to the marked there sectional plane III-III,

FIG. 4a through FIG. 4d a respective embodiment of an integrally designed with abutment elements and coupling element

Fig. 5 shows a third embodiment of a cell structure according to the invention, designed as a freestanding, green partition wall in a vertical cross-section.

In the example of the slope retaining wall constructed as a cellular structure according to FIG. 1, a stem VB forms the wall front. The stem consists of - in front view - checkerboard-like in levels next to each other and one above the other, box-like concrete support elements TE, each with an outwardly inclined front wall W1, two spaced apart side walls W2 and a floor W3. The back of the support elements is open and bounded at the bottom by an upward projection VS which extends over the width of the box. Due to the checkerboard arrangement, gaps L are formed on both sides of a support element in one floor, which gaps are bridged by a support element in the floor above. The side edges of the support elements of one floor each overlap the side edges of a support element in the underlying floor, so that a total of each support element is supported on two underlying support elements. The bottom floor rests in a non-illustrated, non-slip connection on the stable underground UG. In particular, a thrust protection is provided for the lowest, resting on a foundation F supporting element, for. B. in the form of a form-locking element FS engaging in the foundation.

A HF backfill follows the stem VB on the one hand reaches into the cavities of the supporting elements and itself on the other hand backwards to the firm or solidified slope material stretches. That in the cavities of the stem as well Backfill material behind it is used when performing of the building condensed in stages and forms in the mentioned Front gaps embankments B, usually covered with humus or are enriched. The embankments B are supported on the Front and side walls W1, W2 of the support elements, so that a positive connection between the stem and the backfill given is.

In the example, it is a stem that compares wise small, in any case not billed here  Has stability and in its upper areas before Sliding interface or the slope angle of the backfill is arranged. Therefore, the stability of the overall construction factory secured by anchoring according to the invention. This includes, at least in sections, rigid, ins special however completely rigid and thus in anchoring direction tensile and pressure-resistant coupling elements KE, the form and non-positively connected to the support elements TE of the stem and from there in the highly solidified or supportable area of the backfill HF, and at least within a substantial part of the building. In the example there are several in at least one part of the building Coupling elements are provided for each support element. Furthermore, the Coupling elements with at least one each, also in the supportable Area of the backfill HF arranged abutment element WDE Tight and pressure-tight connected by positive locking.

In the manner shown in FIG. 1, the connection between a coupling element KE on the one hand and a supporting element of the stem VB on the other hand is designed as a toothing VZa which can preferably be hung in the vertical direction and thus simplifies the assembly. The teeth are held in positive engagement by the component of the backfill pressure acting from above, which results in an effective simple securing of the positive engagement connection.

The configuration of the toothing VZa shown in FIG. 1 with a downwardly open recess on the coupling elements KE together with an upward projection VS on the associated support element TE is particularly easy to assemble. This projection is in the form of an elongated bar which extends essentially longitudinally to the front of the building and is in positive engagement with a plurality of coupling elements.

In the example execution are for the connection between the Coupling elements and the rear areas of the backfill  beam-like abutment elements WDE with large profile Pages for filling pressure recording. The connection again takes place between the coupling and abutment elements by means of gears that can preferably be hung in the vertical direction VZb. Suitable for installation and complementary to the front toothing VZa is a toothing VZb through a recess open at the top tion on the coupling elements together with a downward projection section formed on the abutment element. Furthermore, the Abutment elements as being essentially horizontal and in Intermediate direction extending parallel to the building front Support elements designed and with adjacent coupling elements positively connected. This results in another one Increase in bond strength in the rear filling area.

The basic construction of the construction shown in FIGS. 2 and 3 is similar to that according to FIG. 1. Corresponding elements are therefore provided with the same reference symbols
The construction according to FIGS. 2 and 3, however, offers an essential further development. This consists, inter alia, in an immediate bar in the rear filling area effective shear force transmission between superposed building levels, eg. B. the representative floors E2 and E3. For this purpose, pairs of support elements TE arranged adjacent to one another at different heights within the stem VB are positively secured to one another against horizontal relative displacement by shear bars SR arranged at a distance from the building front in the backfill HF. It is important in this context first that this thrust transmission takes place between the elements of the different floors in the rear filling area, ie with a relatively large distance from the building front. In this way, tilting moments acting on the stem are avoided or kept to a minimum. Now the filling pressure forces acting horizontally forward within the individual floors can each be diverted to the floor below. This allows the individual floors to be more or less largely supported on the ones below, raising the rear transmission elements by utilizing the high vertical filling pressure components in the rear filling area and tilting the individual supporting elements or forward sections by the rearward arrangement of the thrust transmission can be excluded. A positive connection in both horizontal directions is not in every case indispensable, but generally particularly advantageous according to the invention in view of the stiffness of the structure. As can be seen above all from Fig. 2, an essential construction of the invention is that the shear bar SR has a shear force-transmitting positive connection, preferably by toothing, each to the up and down adjacent counter bearing element WDE and thereby to the corresponding coupling elements KE , which in turn are effective as power transmission elements for the stem (VB). However, direct thrust transmission between the coupling elements can also be considered.

Regarding the coupling element variants according to FIGS. 4a to 4d, it should be noted:

Fig. 4a shows a perspective view of a plate-like shaped coupling element KE relatively large width with corresponding elements of the teeth and VZA VZB. Such a design is particularly suitable for difficult conditions, such as securing against rotation of support elements about a vertical axis. Fig. 4b shows a vertical view of a coupling element KEW, which is formed in one piece with a particularly large and also heavy abutment element WDE and is also suitable for exposed applications. Figs. 4c and 4d show multiple coupling elements KEW, which are in turn integrally formed with large and heavy abutment elements WDE, but having two parallel individual coupling element KE. Here, FIG. 4c a supporting element TE with two single-coupling elements KE and shown in Fig. 4d, the multi-coupling element KEW due to its single-coupling elements KE with two adjacent support elements connected. Furthermore, the single or multiple coupling elements can be both U vis-shaped, T-shaped, I-shaped, both with regard to their sections intended for arrangement in the depth of the backfill, and also with regard to their form-fitting connection with one or more supporting elements be.

Fig. 5 shows a freestanding room partition wall RTM designed cell structure with two oppositely oriented stems VB1 and VB2 and with a backfill HF arranged between them. The coupling elements KE provided here are each connected to two support elements TE1, TE2 of the two stems acting simultaneously as abutment elements and penetrate the backfill arranged between them.

Claims (17)

1. Cell structure, in particular as a slope retaining wall or partition wall, comprising a stem (VB) and a backfill (HF), which is in positive and / or non-positive connection with the stem, the stem (VB) in the area of the structure front in sides - and height direction distributed, preferably trough or box-like solid support elements (TE), characterized in that at least one at least partially rigid, in particular rigid coupling element (KE), preferably a plurality thereof, is provided, the form or are non-positively connected to the stem (VB), extend from there into the depth of the backfill (HF) and are provided or connected with at least one abutment element (WDE) arranged in the area of the backfill (HF). 2. Cell structure according to claim 1, characterized in that a plurality of coupling elements (KE) one into one rear, solidified area of backfill have leading length and that associated abutment elements (WDE) in the solidified backfill area are arranged. 3. Cell structure according to claim 1 or 2, characterized records that at least one coupling element (KEW), preferably a plurality thereof, at least in sections itself as in the backfill arranged abutment elements provided or with are connected in one piece.   4. Cell structure according to claim 3, characterized in that the coupling elements (KEW) provided as abutment elements at least one in the depth of the backfill Neten section U-shaped, T-shaped, I-shaped or plates are formed. 5. Cell structure according to one of the preceding claims, characterized in that at least one coupling element is connected to at least two support elements. 6. Cell structure according to one of the preceding claims, characterized in that at least one support element is connected to at least two coupling elements. 7. Cell structure according to one of the preceding claims, characterized in that at least one of the coupling elements in at least one with a support element which section is U-shaped, T-shaped or I-shaped or is plate-shaped. 8. Cell structure according to one of the preceding claims, characterized in that at least one connection between a coupling element (KE) on the one hand and a Supporting element of the stem (VB) and / or an abutment or Anchoring element on the other hand by a teeth that can be hooked in vertically (VZa, VZb) is formed. 9. Cell structure according to claim 8, characterized in that the teeth (VZa, VZb) by acting from above Backfill pressure are kept in the positive connection.   10. Cell structure according to claim 8 or 9, characterized is characterized by at least one toothing (VZa) a recess at the bottom of the coupling elements (KE) together with an upward projection on assigned support element (TE) is formed. 11. Cell structure according to one of claims 8 to 10, characterized characterized in that at least one gear element on Supporting element (TE) as an elongated, essentially for Building front, longitudinal projection (VS) is formed, with which preferably a plurality of Coupling elements (KE) is connected. 12. Cell structure according to one of the preceding claims, characterized in that at least one toothing (VZb) between a coupling element (KE) and a counter bearing element (WDE) thanks to a recess open at the top on the coupling elements (KE) together with one down projecting section of the abutment element (WDE) is formed. 13. Cell structure according to one of the preceding claims, characterized in that a plurality of abutments element (WDE) as itself essentially hori intermediate and extending along the front of the building Support elements designed and with adjacent coupling elements (KE) non-positively or positively connected are. 14. Cell structure according to claim 13, characterized in that the abutment elements (WDE) as bar-shaped Carrier with large profile sides for the filling pressure absorption are formed.   15. Cell structure, especially as a hill retaining wall or Space dividing wall, including a porch (VB) and a Backfill (HF) with the stem in shape and / or There is a frictional connection, the stem (VB) in the Area of the building front in the lateral and vertical direction distributed, preferably trough-like or box-like Solid-state support elements (TE), especially after one of the preceding claims, characterized in that each pair of at different altitudes of the Stem (VB) arranged support elements (TE) through at a distance from the building front in the backfill (HF) arranged shear bar (SR) against horizontal relative displacement against each other are positively secured. 16. Cell structure according to claim 15, characterized in that the shear bar (SR) has at least a thrust transmitting positive connection, preferably by Gearing, each with adjacent up and down Abutment element (WDE) and / or coupling elements (KE) have as power transmission elements to the stem (VB) are effective. 17. Cell structure according to one of the preceding claims, characterized by training as a room division wall (RTM) with at least two towards each other set oriented stems (VB1, VB2) and between this arranged backfill (HF) and with at least one coupling element (KE), preferably one Most of them, each with two as abutments element provided support elements (TE1, TE2) to each other other oppositely oriented stems (VB1, VB2) are connected and the rear arranged between them reach through the filling (HF).