RU2552281C2 - Device for attachment of reinforced-concrete plates to wall or ceiling structure from reinforced concrete - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: device for attachment of reinforced-concrete plates to a wall or ceiling structure from reinforced concrete includes an insulating body for heat insulation and a reinforcement part that has closed loops from fibrous polymer material as reinforcement elements working for tension and elements with varying profiles from ultrahigh-strength concrete, which work for bending compression and for shear, with that, horizontally located loops are laid in the insulating body between the reinforced-concrete plate to be attached and the wall or ceiling structure, and elements working for bending compression and for shear are integrated into the insulating body.

EFFECT: creation of a device for attachment of reinforced-concrete plates to a wall or ceiling structure from reinforced concrete with an insulating body for heat insulation and a reinforcement part.

12 cl, 7 dwg

Description

The invention relates to a device for connecting reinforced concrete slabs to a wall or ceiling structure made of reinforced concrete with an insulating body for thermal insulation and a reinforcing part that has reinforcing elements working in tension and compression.

Along with the highest heat-insulating effect of this kind, devices must withstand generally high loads by bending force and transverse force. The scope is very diverse and covers the use in the case of speakers, as well as propped up balcony and terrace plates, through plates that protrude from the external structure of the building, the supporting areas of the loggias, thermal separation from the attics and window sills to consoles and wall panels.

Known devices for freely protruding reinforced concrete slabs, the upper tensile reinforcement of which is performed depending on the magnitude of the bearing capacity. At the same time, in the transition zone of the heat-insulating plane, a high-quality reinforcing profile of stainless stainless steel is used. It, for example, by means of resistance pressure welding is connected to an adjacent high-quality reinforcing profile. The brackets for the perception of transverse forces are made of stainless steel of the same grade as the tensile rods, and the connection for the connecting fittings, in turn, is carried out by welding. As a heat-insulating material in the transition region, for example, polystyrene rigid foam can be used. Modules from, for example, highly loaded granular concrete reinforced with steel microfibres are integrated into it in the compression zone.

For well-known products, which are also referred to as "insulating frames", it is common that the bending load-bearing capacity decreases with increasing thermal resistance. The perception of shear forces is different for these products. In some products, lateral force is perceived by brackets. The insulating frames developed by the applicant have a frame structure that transmits both moments and transverse forces. Another solution is to arrange shear steel sheets, which, apart from the transmission of moments, are also used to absorb shear forces. The transmission of lateral force by means of brackets, respectively, working on the shear of steel sheets, has a positive effect on deformation, since negligibly small shear distortions are established in the transition region due to higher shear stiffness. In the case of such a frame of the supporting system, on the contrary, additional deformations from the transverse force component must be constantly taken into account. Systems that separately transmit torques and lateral forces generally become preferred in relation to load adaptation.

However, the disadvantage of the known devices consists in general in insufficient decoupling of the load-bearing capacity of the moments and lateral forces and in costly manufacture.

The invention is involved in order, when using highly loaded materials, to respectively improve the thermal insulation in the transition region of the insulating frames, and to increase the flexibility of the connecting device to such an extent that, by analogy with modular systems, many geometric boundary conditions can be realized using the same product with simple installation steps. The product must be optimized so that, through simple gradation (step-by-step) capabilities, in order to fit the respective load-bearing requirements, the product's efficiency can also be increased.

According to the invention, the connecting device of the type indicated in the introductory part is characterized in that the reinforcing part has closed loops of fibrous polymer material as tensile reinforcing elements and compression and bending and shear elements with variable profiles of ultra-high-strength (ultra-high-strength) concrete (UHPFRC ), and horizontally located loops are laid in an insulating body between the reinforced concrete slab to be connected and the wall or ceiling structure ktsiey and working compressive flexural and shear elements are integrated in the insulating body.

According to one preferred embodiment of the invention, the closed loops of the tensile reinforcing member consist of carbon fiber reinforced polymer material (CFK) or fiberglass reinforced polymer material (GFK).

In accordance with one further feature of the invention, the bending and shear compressive elements consist of quality concrete (grade) UHPFRC.

The invention and its other features are further explained in more detail on the basis of embodiments with reference to the drawings.

Figure 1 is a schematic side view of the device according to the invention;

Figure 2 is a principal front view of the device;

Figure 3 is a top view of the device;

4 is a top view of another embodiment;

Figure 5 is a schematic perspective view;

6 is a sectional view of an improved device according to the invention; and

7 is a top view of an improved device according to the invention.

The connecting device shown in the drawings for attaching reinforced concrete slabs 1 to a wall or ceiling structure 2 has an insulating body 3 for thermal insulation and a reinforcing part 4. The reinforcing part 4 in the area of tensile stresses consists of closed loops 4 ', for example, of a fiber polymer material, connection to the reinforcement of the slab, and in the area of compression stress during bending and shear, it consists of 4 ”differently profiled elements of ultra-high-strength (ultra-high-strength) concrete (UHPFRC - Ultra High Performance Fiber Reinforced Concrete). The ends of the loops 4 'are engaged with the U-shaped brackets 5 of the connecting fittings.

Compared with stainless steel reinforcing bars, the invention contributes to insignificant cross-sectional areas and significantly reduced heat loss, and also through various loop geometries provides high adaptability (adaptation) to the bearing capacity.

In order to transmit tensile forces in accordance with the invention, an endless loop can be provided, for example, of carbon fiber reinforced polymer material (CFK) or fiberglass reinforced polymer material (GFK). The manufacture of the loop can be carried out, in particular, using longitudinally oriented fibers in the direction of the loops, which are braided by a layer of fibers twisted by 90 °, thereby achieving a sufficiently high compressive strength across the fibers. Loop forming allows power transmission despite poor connection between concrete and the loop. By changing the geometry of the hinges, the load-bearing capacity can easily be adapted / adjusted to the relevant requirements. The most important input parameters are the loop height and the radius of the loop. Using both of these values, the bending stresses of the reinforcement on the surrounding concrete are regulated, and thereby also the compressive stress across the fibers per loop. By means of the compression UHPFRC elements located in the outermost compressed edge, a large internal lever arm is achieved, whereby the forces acting on the bearing elements are minimized. Figures 3 and 4 show differently made connecting devices according to the invention.

In the framework of the invention, the insulating function can be significantly enhanced by the use of highly efficient materials UHPFRC and CFK / GFK. By forming an open compressed belt of tapering UHPFRC elements, both the required volume of concrete and the surfaces that lose heat can be kept to a minimum.

In order to increase the load-transferring surfaces between ordinary concrete and the bending and shear compressive elements 4 ″, these UHPFRC elements can expand at the ends and are also preferably profiled, respectively provided with 4 ″ protruding triangular ribs, as shown, in particular, in FIGS. 5-7. Through this form of the type of "dog bone" thermal conductivity is kept at an insignificant level.

Due to the extremely high tensile strength of CFK / GFK, the cross sections of the tensile elements 4 'can be reduced so much that the heat insulating body is almost not interrupted. Thermal conductivity through tensile elements is greatly reduced compared to stainless steel due to the very small heat transfer total surface.

Further, the construction according to the invention allows an economical gradation of bearing capacity. In the case of flexural bearing capacity in the region of, for example, 50 kNm / m, twice the equivalent thermal resistance (thickness of the insulating material, for example, 8 cm) with respect to existing products is expected. These excellent properties are obtained mainly from the use of materials with high strength, as a result of which insignificant cross-sections are required and, thus, the heat-insulating body is only slightly weakened.

Another significant advantage of the invention is manifested when insulating wicker frames are used in products. Without exception, all welding work that is necessary in the case of products used so far is eliminated. Since even assembly is simplified, salary costs can be greatly reduced.

The invention should allow use in passive houses (i.e., houses without an active heating system). A prerequisite for a passive house standard is an annual heat consumption of 15 kWh / m ² , which means significant energy savings compared to energy-saving houses (houses with low energy consumption).

Due to the use of high-strength CFK / GFK material in the tensile region and UHPFRC in the compressive region, as well as the corresponding savings, they began to receive a significant improvement in the environmental sustainability of the product, since the energy requirement for manufacturing 1 m ^{3 of} UHPFRC is only 5% from the energy requirement for manufacturing the same amount of steel with the same compressive strength.

Claims (12)

1. A device for attaching reinforced concrete slabs (1) to a wall or ceiling structure (2) made of reinforced concrete, containing an insulating body (3) for thermal insulation and a reinforcing part, which has tensile and compressive elements, characterized in that the reinforcing part has closed loops (4 ') of fibrous polymeric material as tensile reinforcing elements and compression (bending and shear) elements (4' ') with varying profiles of ultra-high-strength concrete, and the horizon The loops (4 ') are located in the insulating body (3) between the reinforced concrete slab (1) to be connected and the wall or ceiling structure (2), while the compression (bending and shear) elements (4' ') are integrated into the insulating body (3). 2. The device according to claim 1, characterized in that the closed loops (4 ') of the tensile reinforcing element consist of carbon fiber reinforced polymer material (CFK) or fiberglass reinforced material (GFK). 3. The device according to claim 1 or 2, characterized in that the compression (bending and shear) elements (4 ") are made of concrete of UHPFRC quality. 4. The device according to p. 1 or 2, characterized in that the hinges (4 ') are laid, preferably glued, into the grooves of the insulating body (3). 5. The device according to p. 3, characterized in that the hinges (4 ') are laid, preferably glued, into the grooves of the insulating body (3). 6. The device according to one of paragraphs. 1, 2 or 5, characterized in that the ends of the loops (4 ') are engaged with the U-shaped loops (5) of the connecting fittings. 7. The device according to claim 3, characterized in that the ends of the loops (4 ') are engaged with the U-shaped loops (5) of the connecting fittings. 8. The device according to claim 4, characterized in that the ends of the loops (4 ') are engaged with the U-shaped loops (5) of the connecting fittings. 9. The device according to one of paragraphs. 1, 2, 5, 7, or 8, characterized in that the compression (bending and shear) elements (4 ″) in the top view are made essentially in the shape of a “bone” and are preferably provided with protruding triangular ribs (4 ' ''). 10. The device according to p. 3, characterized in that the compression (bending and shear) elements (4 ") in the top view are made essentially in the shape of a" dog bone "and are preferably provided with protruding triangular ribs (4" ") . 11. The device according to claim 4, characterized in that the compression (bending and shear) elements (4 ″) in the top view are made essentially in the shape of a “bone” and are preferably provided with protruding triangular ribs (4 ″ ) 12. The device according to claim 6, characterized in that the compression (bending and shear) elements (4 ″) in the top view are made essentially in the form of a “bone” and are preferably provided with protruding triangular ribs (4 ″ )

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