DE10049293A1 - Modular construction element for space lattice structure esp. for retaining and noise protection walls has longitudinal girders with varying cross sectional height and downward-facing wedge parts - Google Patents

Abstract

The element is a frame structure (RK) with longitudinal (LTR) and cross girders (QT) at right angles to each other. The cross sectional height of a longitudinal girder decreases or increases relative to its fitted position in a direction at right angles to the structure front. The lower part of longitudinal girder has a wedge-shaped cross sectional part (KQ) with a downward facing wedge tip (KS) with an acute angle of max. 90 deg , pref. max. 65 deg .

Description

The invention relates to a component for space lattice structures with mass filling, in particular for retaining and / or soundproof walls, with the following features:

• - It is a closed or open, one-piece or multi-part assembled trained frame body (RK) with at least one rear, regarding the installation position at a distance from and essentially along the front of the structure extending longitudinal member (LTR) and with at least one with regard to the installation position in the angle, in particular in essentially at right angles, extending to the front of the structure Cross member (QT) provided;
• - The longitudinal member (LTR) has at least essentially or at least in sections a triangular or polygonal, in particular quadrangular, of planes at least in sections Longitudinal surface limited profile.

Components of this type are widely known in the art. At the Strive to such constructions for by earth pressure u. a. always more heavily used and more exposed arranged support and / or However, the need to use soundproof walls was encountered of undesirably large dimensions and the same material expenditure. In view of these and other considerations, u. a. also those of resource conservation and sustainability as well as the rational producibility comprises the object of the present invention the creation of building elements that make progress in terms of enable at least one of the aforementioned criteria.  

The inventive solution to this problem is determined by the Features of claim 1.

The disclosure of the present invention also includes certain Developments of the immediate determined in claim 1 The subject matter. Such trainings are through Determined and have characteristics of the subordinate claims essential technical and inventive meaning. Your characteristics are, however, for an advanced realization of the immediate Subject of the invention not absolutely necessary, but open up new optimization possibilities of the same.

Features of the invention and major advantages are now under Reference to those shown schematically in the drawings Exemplary embodiments explained.

Fig. 1 shows a section of a frame-shaped component according to claim 1, in which at least in part of the longitudinal beam (LTR) whose cross-sectional height is increasing or decreasing with respect to the installation position in the direction transverse to the structure front. In its lower area with respect to the installation position, the longitudinal beam comprises an acute-angled wedge-shaped cross-sectional area (KQ) with a wedge apex (KS) pointing downwards. The following design and dimensioning features have proven to be particularly advantageous in this context:

The downward wedge vertex (KS) of the side member (LTR) forms an angle (w) of at most about 90 °, in particular of at most about 65 °. The inside of the component facing wedge flank surface (F1) forms with at least one sectionally flat top surface (F3) of the side member (LTR) an angle (x) of measured across the wedge cross section at most about 88 °, in particular at most about 80 °.  

Furthermore, one faces the interior of the component frame Wedge flank surface (F1) with a plane that is at least in sections Top surface (F3) of the side member (LTR) together and forms thus an inner edge (KI) of the component frame. Furthermore it has proved to be particularly effective if one of the outside of the frame of the component facing wedge flank surface (F2) with a at least in sections flat top surface (F3) of the Longitudinal member (LTR) a measured across the wedge cross-section Angle (y) of at most about 45 °, in particular of at most about Forms 40 °. This is especially true if one is the frame outside of the component facing profile surface (F4) of the Longitudinal beam (LTR) with a flat at least in sections Top surface (F3) of the side member (LT) one over the wedge cross-section measured angle (z) of at most about 88 °, forms in particular of at most about 85 °. Furthermore, it has increased many times a design in such a way that it is advantageous that a Profile surface facing the outer frame (F4) of the side member (LTR) with an at least sectionally flat top surface (F3) of the The longitudinal member collides and an outer edge (KA) of the Component frame forms.

The design according to the invention allows, in particular, an advantageously simple optimization of the reinforcement position in the case of components made of reinforced concrete. For this purpose, a reinforcing strand (A1) running in the longitudinal direction of the beam can be arranged within the cross-sectional angle (z) on the outer edge of the component (KA), due to the collision of a profile surface (F4) of the longitudinal beam (LTR) facing the frame exterior with an at least sectionally flat top surface (F3) of the side member is formed. Next, FIG. 1 shows an optimization variant of the longitudinal carrier is arranged in a plurality of armor strands (A1, A2) within the longitudinal support cross-section in the region of the top side. In addition, for further optimization, a reinforcement strand (A3) running in the longitudinal direction of the beam can be arranged within the cross-sectional angle (w) on the downward wedge vertex (KS) of the longitudinal beam (LTR).

Excellent results result from the use of Components of the aforementioned type in structures with space lattice Structure and mass filling as well as embankment, slope or Filling material on the back, as used especially for support and / or soundproof wall. Here you can Side members (LTR) with their wedge-shaped cross-sectional areas (KQ) on the back of the space lattice structure and in the area of embankment, slope or fill material located there become.

Such a structure with a plurality of superposed angeord Neten, here for example with a closed one-piece frame formed components (BE) is indicated in Fig. 2. The pressure forces due to the earth backfilling (not shown) are illustrated by the arrow PE.

With one of the listed features or in particular one Combination of several of these can be related to one trapezoidal cross-sectional design of the side member u. a. the following achieve progressive effects:

The comparatively long diagonal of the side member cross section is statically particularly efficient because it works from the mountain side Earth pressure can be absorbed with a higher section modulus, also because of the comparatively widely spaced reinforcement strands.

The side surfaces of the side member profile converging at an acute angle allow easy stripping of the frame body made of concrete. The inclined position of the side surfaces and above all the comparatively strong inclined position of the lower surface of the wedge or trapezoidal profile favor an at least approximately cavity-free filling of the space lattice wall with earth or bulk material. In a tier arrangement according to FIG. 2, the components arranged one above the other are secured by means of (or only indicated by dash-dotted lines) anchoring or compression against displacement.

In Fig. 3, a closed frame-shaped component is shown with the earth-side or mountain-side side member LTR and front side member LTF and two cross members QT.

Fig. 4 shows the profile of the front side member in cross section. Within a building, the longitudinal member (LTR) is in turn arranged on the back of the space lattice structure and is in support connection with the embankment, slope or fill material located there. The front surface (OF) and the rear surface of the (OR) side member (LTF) form an angle between 2 ° and 15 ° which is open downwards with respect to the installation position. Furthermore, it is advantageous if the front surface (OF) of the side member (LTF) is arranged at least in sections with respect to the frame normal direction (N) ascending towards the inside of the frame at an angle between 2 ° and 15 °. Then at least one projecting flange section (FA) is provided on the inside surface of the side member (LTF), in the example in the area of the inside edge of the top member of the side member (LTF).

The special properties of these variants are as follows:

The front side members can have a closed wall outside Form area as this B. for walls along a watercourse or for Quay walls is required. The front surfaces of the individual components have a slight slope forward. This makes these surfaces  Rain exposed more and are kept free of pollution. The lower thicker front panels of the components can be attached to the outer lower edge form a drip nose so that rainwater does not penetrate the interior of the space grille. However, it can be in certain cases, for example with sufficient internal drainage, vice versa rainwater should not be allowed on the lower front drain elements, but into the interior of the space grille deduce what results in less pollution. The top edges the front side members have a certain distance, e.g. B. from 2 to 10 cm, from the top edges of the associated cross beams, which are in a Layer arrangement lie on top of each other. They are also Cross-section of the front side members slightly on the inside of the frame bevelled in order to put the component to be placed in the correct one Able to manage. Furthermore, the storage and transport Risk of damage to the visible surfaces on their lower edge reduced. Then the lower edges of the front side members have one greater distance with respect to the above-mentioned upper edge distance from Z. B. 3 to 11 cm from the lower edges of the associated cross members. This results in the one above the other between the front side members lying floors a horizontal gap of z. B. 0.5 to 1 cm thick, while the associated cross beams lie on top of each other. It will be so ensures that the high vertical loads only between the superimposed surface sections of the cross beams, not but about the fragile and aesthetically relevant edges of the Front side members are transmitted. Of particular importance also one on the inside of the frame surface of the front length carrier projecting flange portion (FA), which is an essential Reinforcement and stiffening of this beam or considerable Material savings possible.

Overall, it is understood that instead of the ones shown in the examples, closed frame body if necessary also open, for. B. bracket shaped frame body designed and used according to the invention can be.  

It also goes without saying that at least one of the supports provided in components according to the invention can optionally have a profile with at least one curved section. As a result, the basic function of the polygonal, in particular trapezoidal or triangular, profiles designed or used according to the invention is not disturbed. On the other hand, useful effects can be achieved in such a way, e.g. B. with regard to the easier shaping of concrete elements. In this regard, a curvature variant F1a of the profile surface F1 shown in dash-dotted lines is provided in FIG. 1.

Claims (16)

1. Component for space lattice structures with mass filling, in particular for retaining and / or soundproof walls, with the following features:

• a) it is a closed or open, one-piece or multi-part frame body (RK) with at least one rear, with respect to the installation position at a distance from and substantially along the front of the structure longitudinal member (LTR) and with at least one with respect to the installation position in Angles, in particular substantially at right angles, to the front cross member (QT) are provided;
• b) the longitudinal member (LTR) has, at least in sections, a triangular or polygonal, in particular quadrangular, profile delimited by at least essentially or at least partially flat longitudinal surfaces;

characterized by the following features:

• a) at least in a part of the longitudinal beam (LTR), its cross-sectional height is designed to increase or decrease with respect to the installation position in the direction transverse to the structure front;
• b) in its lower region with respect to the installation position, the longitudinal beam comprises an acute-angled wedge-shaped cross-sectional region (KQ) with a wedge apex (KS) directed downwards.

2. Component according to claim 1, characterized in that the downward apex (KS) of the side member (LTR) an angle (w) of at most about 90 °, in particular of at most forms about 65 °. 3. Component according to claim 1 or 2, characterized in that one facing the frame interior of the component Wedge flank surface (F1) with at least sections flat top surface (F3) of the side member (LTR) one over the wedge cross-section measured angle (x) of at most forms about 88 °, in particular of at most about 80 °. 4. Component according to one of the preceding claims, characterized characterized in that the inside of the frame of the component facing wedge flank surface (F1) with at least a section as flat top surface (F3) of the side member (LTR) together size and forms an inner edge (KI) of the component frame. 5. Component according to one of the preceding claims, characterized characterized in that the one outside the frame of the component facing wedge flank surface (F2) with at least a section wise flat top surface (F3) of the side member (LTR) one angle (y) of measured over the wedge cross section forms at most about 45 °, in particular of at most about 40 °.   6. Component according to one of the preceding claims, characterized characterized in that the one outside the frame of the component facing profile surface (F4) of the side member (LTR) with a at least in sections flat top surface (F3) of the Longitudinal beam (LT) measured across the wedge cross-section NEN angle (z) of at most about 88 °, in particular of at most forms about 85 °. 7. Component according to one of the preceding claims, in particular dere according to claim 6, characterized in that the Profile surface (F4) of the side member facing the frame (LTR) with an at least sectionally flat upper sides surface (F3) of the side member and an outer edge (KA) of the component frame forms. 8. The component according to claim 7, characterized in that at least one reinforcement running in the longitudinal direction of the beam strand (A1) within the cross-sectional angle (z) on the Component outer edge (KA) is arranged by the Collision of one facing the frame exterior Profile surface (F4) of the side member (LTR) with at least one sectionally flat top surface (F3) of the side member is formed. 9. Component according to one of the preceding claims, in particular dere according to claim 8, characterized in that a plurality of reinforcement strands (A1, A2) within the side member arranged cross-section in the region of the top of the side member is.   10. Component according to one of the preceding claims, in particular dere according to claim 9, characterized in that at least a reinforcement strand (A3) running in the longitudinal direction of the beam downward within the cross-sectional angle (w) Wedge apex (KS) of the side member (LTR) is arranged. 11. The component according to one of the preceding claims, characterized in that the front surface (OF) and the rear surface of the (OR) side member (LTF) with each other one open downwards with regard to the installation position Form an angle between 2 ° and 15 °. 12. Component according to one of the preceding claims, characterized in that the front surface (OF) of the longitudinal member (LTF) at least in sections with respect to the frame normal direction (N) increasing to Inside the frame at an angle between 2 ° and 15 ° is inclined. 13. Component according to one of the preceding claims, characterized in that on the inside of the frame Surface of the side member (LTF) at least down projecting flange section (FA) is provided. 14. The component according to claim 13, characterized in that the projecting flange section (FA) in the area of top edge of the side member inside the frame (LTF) is arranged.   15. Structure with space lattice structure made of frame-shaped construction elements and mass filling as well as embankment, slope or Filling material on its back, in particular support and / or Soundproofing wall, characterized by components according to a or more of claims 1 to 14, whose side members (LTR) with their wedge-shaped cross-sectional areas (KQ) on the back of the space lattice structure and in the area from there Embankment, slope or fill material are arranged. 16. Building according to claim 15, characterized by components according to one or more of claims 1 to 10, with the following features:

• a) at least one component is provided which has at least one side member (LTR) with a profile surface (F4) facing the frame exterior, which abuts an at least sectionally flat top surface (F3) of the side member and forms an outer edge (KA) of the component frame;
• b) the profile surface (F4) of the side member (LTR) facing the outside of the frame is arranged on the back of the space lattice support structure and is in support connection with embankment, slope or fill material located there.