DE10254043A1 - Composite construction of high load bearing capacity has profiled ribs are used as means of connection and are rigidly connected to wood or derived timber product and protrude into concrete - Google Patents

Abstract

The composite construction of high load bearing capacity consists of wood (3) or derived timber product and concrete (1) which are connected face parallel. Profiled ribs (2) are used as a means of connection and are rigidly connected to the wood and protrude into the concrete. The ribs consist of wood or derived timber product and have an undercut as profiling. The ribs, which have a negative flank slope, are constructed concavely or convexly, or with predetermined inclination angles, can have an end anchoring, are can be arranged individually or on a support plate.

Description

The invention relates to wood / concrete composite structures, Wood-based material / concrete composite structures and wood / wood-based material / concrete composite structures with high load capacity, high-performance materials are used to manufacture them.

The composite construction can both in the new building as well as in the upgrading existing wood or wood-based material constructions as load-bearing and / or space enclosing Component are used. In bridge building can be used as a load-bearing carriageway slab. Other uses result from the weight saving compared to standard constructions - if necessary still reinforced through the use of lightweight concrete - for problematic subsoil, in the case of top-ups or conversions.

As components for wood-concrete composite cross sections are normal concretes and the solid wood that has been used for some time. For the Interaction of the individual cross-sectional parts and thus for the load-bearing behavior of the overall composite cross-section are of particular importance lanyard to be used. You decide on the Compound effect, the manufacturing effort and cost of the whole Composite construction.

So if the properties of composite structures should be improved, then this is done primarily via a Optimization of composite funds. The following are therefore known and lanyards used in practice listed to to represent the state of the art.

Applications of wood-concrete composite structures can be traced back to the 1940s. The first recent research projects were carried out in 1984 by Godycki et al. and later by Natterer, Blaß and further carried out. There have been shear and bending tests for nail and incision composite materials carried out.

The SFS system from Stadler, which has been known in practice since 1996, provides for an arrangement of inclined special screws that are screwed into the wooden beams through the planking (approval number Z-9.1-342 and published specification DE 40 29 134 A1 ). Limit values for the transmission of shear forces from the concrete are assigned to the screws.

In the utility model DE 298 15 614 U1 proposes a composite screw for a wood-concrete structure that has two different profiles. The lower zone contains a wood thread, the upper screw section has a scaly surface in order to achieve bedding in the concrete.

Further punctiform connecting means for the transfer of shear force in wood composite bending beams are in DE 100 39 264 A1 . DE 299 23 879 U1 and DE 695 18 396 T2 presented.

The headed dowels known from steel-concrete composite construction are used in DE 297 06 301 U1 and EP 1 013 840 B1 proposed for wood-concrete composite construction.

The profile sheets also known from steel-concrete composite construction are in DE 196 02 400 A1 and DE 196 40 880 A1 arranged as formwork for the concrete at right angles to the direction of load on the wooden beams. The bond between wood and concrete is achieved by screws in the depth corrugation, possibly reinforced with a steel angle.

In DE 298 24 534 U1 describes a board stack element, between the lamellae of which sheets or squared timbers are arranged, which protrude as webs into the concrete slab. The bond is not made via an undercut of the webs, but via "shear force anchors" which are inserted into recesses in the webs.

Examples of positive connections with rod-shaped connectors to absorb the tensile forces are concrete cams with steel pins and reinforced concrete cams in plywood panels as well as those at ETH Lausanne together with Hilti AG, Schaan developed connector HILTI HBV. With the HILTI dowels HBV is a re-tensionable fastening anchor glued into the wood.

The composite structures described above have a linear or point-shaped composite. To improve the load-bearing behavior in the composite joint, however, a surface-acting composite was also sought. In the published application DE 197 29 058 A1 an adhesive connection is proposed.

Have the technical solutions described a number of disadvantages.

The previously known compound for wood-concrete composite cross-sections are assembly and cost intensive and not very ductile. A high degree of prefabrication is necessary for slim lanyards (screws, nails, etc.) not possible.

If adhesive bonds are to be used to produce a composite surface, depending on the adhesive, only precast concrete parts can be used. For the system after DE 197 29 058 A1 can be used in-situ concrete, a implementation in practice has not been successful for technical or economic reasons.

Furthermore, the lanyards only examined in combination with normal concrete. It means that the previously known connecting means not to the use of newly developed high-performance concrete that is now ready for use are adjusted.

In the field of wood-concrete composite construction there are a large number of research results, property rights and publications In practice, composite structures are available. However, no inexpensive, sufficiently ductile connecting means has yet been found which allows large quantities of wood-concrete composite structures to be manufactured in an economically interesting and competitive manner.

The causes of the disadvantages is as follows.

From the small parts (system of Meierhofer SFS) there are a large number of connection points and thus a high manufacturing effort in situ. The possible degree of prefabrication is small because the lanyards are too slim for transportation several stacked elements to enable.

Lean lanyards such as Screws or nails under longitudinal thrust due to the relatively large Shifts between concrete and wood / wood material to a reduced Composite action. The load capacity the composite cross-section including that from the composite effect resulting positive properties is reduced.

In the case of punctiform arrangement of the connecting means there are different levels of stress on the composite. The previously known connecting means are not ductile enough, i.e. the plastic deformation capacity is too low to redistribute the force to reach less stressed areas. A failure follows the lanyard in the most stressed areas, without the carrying capacity would be exhausted in less stressed areas. Below also fail the connecting means that had been less stressed up to that point - the composite cross section "tears open" in the joint

The execution of concrete cams or Notch, if necessary in connection with re-tensionable fastening anchors leads to a relatively high shear stiffness, but at the same time requires a high workload and is for upgrading existing wooden structures not very suitable. They are also not ductile enough.

The aim of the invention is to create a two-dimensional composite that is not very labor-intensive to manufacture between the concrete and wood / wood-based material layer to create a composite cross-section with improved load capacity to achieve as well as the cost and time expenditure compared to reduce known methods. The result is a variable use and easy to handle construction for universal tasks, which has a high degree of prefabrication and optionally with high strength and Executed normal concreting can be.

In the case of problematic subsoil or when building in existing buildings there is a reduction in the proportion of own load the construction makes sense. Already through the use of wood The weight saved should be achieved by using high-strength or Lightweight concrete reinforced become.

This requires a compound that is sufficient is ductile and equidistant can be arranged. At the same time, an industrial prefabrication is said possible to be without the individual adaptability that is particularly important when building existing or unusual Geometry essential is to affect. These features mentioned are intended for easy handling the construction site and to rationalize the construction process and thus damping of construction costs.

In addition, the lanyard must be used be suitable for all types of concrete.

Accordingly, the invention has the task a shear-resistant bond between the concrete and a wood / wood-based material layer to ensure. It is supposed to be a permanent and stable flat bond between concrete and wood reliably achieved by activating surface frictional forces become. Furthermore, the more recently available are said to be High-performance concrete as well as newly developed solid wood and wood materials tested and significantly improved with mechanical properties Success. It is the "zipper effect" by a qualified Arrangement of the connecting means according to the course of forces or even at equal intervals can be avoided by a highly ductile lanyard.

The invention is based on the knowledge based on that solve the task lets through Profiled ribs embedded in the concrete, using pin-shaped connecting means or gluing force-fitting are connected to the wood / wood-based material.

According to the invention, the object is achieved as follows.

A composite cross section is created that consists of wood or wood-based material and concrete, the latter being normal concrete or can be high performance concrete. Between the wood or wood-based material layer and the concrete layer are arranged profiled ribs, which in protrude the concrete slab and with the wood or wood-based material are firmly connected by connecting means. The ribs are there made of wood or wooden materials and run parallel to the main direction of load of the composite cross section.

The geometry of the ribs has one Profiling on, preferably an undercut, that is one negative slope. Tilt and shape of the ribs to Example concave, convex or variable angle of inclination, can be modified, amended or added become. additionally an end anchorage can be provided. The ribs can be individually or on a carrier plate applied together.

The composite effect arises from the undercut of the ribs. The resulting clamping effect leads to an activation of the frictional forces and creates a flat composite. The resulting joint load-bearing capacity of the cross-sectional parts as a composite cross-section leads to the advantages already mentioned.

The geometric shape as well as the arrangement of the ribs parallel to the bearing direction of the composite cross section a common longitudinal shift all lanyards. In addition to the high ductility in the Compound joint results from this the possibility of equidistantly connecting the connecting means, so with constant intervals independent of Course of the longitudinal thrust to arrange. An additional end anchor may be required.

The longitudinal thrust forces can either be by means of pin-shaped connecting means (e.g. screws, nails, o.a.) or transferred by glue the tensile forces at right angles to the composite joint are transferred by means of pin or screw-shaped connecting means. If the ribs are subjected to transverse tension due to their fiber orientation, these fasteners also serve as transverse tensile reinforcement.

Those embedded in the concrete slabs Ribs are created by means of helical Lanyards and / or in combination with glue with the wood or the wood-based material is resistant to shear and tensile strength. About the adhesion to increase the rib can be connected with screws that have two threads with different pitch have. The arrangement of the pin-shaped connecting means is both inclined and vertical possible. The helical connecting means mentioned can also be designed as pins, for example as screws, nails, anchors, dowels, Brackets, bolts or the like.

In the manufacture of the composite structure including its Cross-sectional parts become a high degree of prefabrication and industrial Manufacturing enables. The composite means between the ribs and wood / wood material mechanically protected by the more robust ribs. So that is both the manufacture on the construction site as well as the prefabrication and transportation of Semi-finished parts and finished parts possible. Semi-finished parts exist from elementary wooden components, such as. e.g. Board stacking elements or plywood panels with ribs already applied. Concreting and, if necessary, placing the reinforcement is then provided by the customer (only required for semi-finished parts). The finished parts already have a wood / wood-material-concrete cross-section.

Because of the element and easy adaptability of the system are individual solutions possible. The reduction in assembly time leads to better weather resistance and therefore a higher one Execution quality of the construction. Industrial quality assurance procedures become applicable. By simplifying the construction process on-site error sources eliminated.

The planner now has the option of to devalue a construction geared to the requirements. For example, if necessary, the clamping effect by screwing with two Threads of different pitch reinforced become.

By optimizing the layer thicknesses and the strength of the zero line can be set so that the wood material layer the tensile forces and the concrete layer the Pressure forces takes over. In certain circumstances reinforcement of the concrete layer can be avoided.

The concrete layer can be made of normal concrete or a high-performance concrete such as self-compacting concrete, self-compacting Lightweight concrete, high-strength concrete, fiber concrete or the like exist.

It should be noted that the use high-strength high-performance concretes to reinforce the zipper effect leads.

The invention is based on exemplary embodiments and map closer explained.

A general perspective view is shown in 1 , The composite cross-section is created by the shear-resistant connection of the concrete slab with the wood / wood-based board. The transmission of force between the concrete slab and the rib is always ensured by the undercut geometry ( 7 . 8th ) .. On the other hand, the connection means in the joint between the rib and the wood / wood-based panel is variable. Due to the undercut geometry of the ribs, frictional forces are activated. The resulting longitudinal thrust and transverse tensile forces must be absorbed by the connecting means.

In the subsequent concreting, that will be Wooden element also used as formwork.

Example 1: ( 3 )

Profiled ribs ( 2 ) according to 7 respectively. 8th are placed on a wooden component ( 3 ) such as board stacking element, laminated veneer wood panel or similar. attached. Pin-shaped connecting means ( 4 ), as in 9 and 10 shown, used, which simultaneously absorb the longitudinal thrust and tensile forces. The wood layer (s) support the concrete layer and serve as formwork during the concreting process.

example 2 : ( 4 )

For the wood layer ( 3 ) thick-plywood is used, with the top layer being milled out in the form of ribs. Between ribs ( 2 ) and wood / wood-based panel ( 3 ) becomes a frictional glue joint ( 5 ) trained, which absorbs the longitudinal thrust. The tensile forces are generated by rod-shaped connecting means ( 9 . 10 ) added, which also form the transverse tensile reinforcement for the rib profile.

Use as a composite ceiling in building construction or as a load-bearing carriageway slab in bridge construction: ( 1 )

Horizontal installation of a wood-concrete composite structure

Use as a composite wall: ( 2 )

Vertical installation position of the composite cross-section, which in this case has a three-layer structure. The outer surfaces are covered by two wood or wood-based panels ( 3 ) with attached ribs ( 2 ) educated. The space is made void-free with reinforced or unreinforced concrete ( 1 ) filled.

The illustrations belonging to the exemplary embodiment demonstrate:

1 perspective views of the composite cross section in a horizontal installation position, general illustration (connecting means not shown)

2 perspective view of the composite cross-section in the vertical installation position, general illustration (connecting means not shown)

3 Composite cross-section, example 1: Ribs screwed onto a wooden layer (e.g. board stacking element, solid wood or wood-based panel)

4 Composite cross-section, example 2: ribs in the top layer of the thick-plywood milled and glued, pin-shaped connecting means only transmit tensile forces

5 Longitudinal section through composite cross-section, pin-shaped connecting means installed at 90 °

6 Longitudinal section through composite cross-section, pin-shaped connecting means installed inclined

7 possible profile shapes of the rib

8th Different arrangement of the ribs: single rib or combined on a carrier plate (pin-shaped connecting means in the carrier plate for absorbing the tensile forces not shown)

9 pin-shaped connecting means (screw forms)

10 pin-shaped connecting means (clips, screws, nails)

Claims (7)

Composite construction of high load-bearing capacity made of wood or wood-based material and concrete, characterized in that wood or wood-based material and concrete are connected flat, whereby profiled ribs are used as connecting means between wood or wood-based material and concrete, which are firmly connected to the wood or wood-based material and into the concrete protrude, whereby the ribs are made of wood or wood-based material and have an undercut as a profile. Composite construction according to claim 1, characterized in that the ribs, which have a negative slope, concave or are convex or with a predetermined angle of inclination, a Can have end anchorage individually or on a carrier plate are arranged. Composite construction according to claims 1 and 2, characterized in that the connection means for connection the ribs on wood or wooden material constructions are pin-shaped are also helical, and that the helical Design has different threads. Composite construction according to claims 1 to 2, characterized in that the ribs on the wood or wood-based construction are glued. Composite construction according to claims 1 to 4, characterized in that in addition to normal concrete also high-performance concrete be used. Composite construction according to claims 1 to 5, characterized in that the composite structures are prefabricated are. Composite construction according to claims 1 to 6, characterized in that the ribs parallel to the main direction of support of the composite cross section.