CZ25368U1 - Composite wood-concrete coupled overhead beam - Google Patents

Description

The Industrial Property Office does not ascertain in the registration procedure whether the subject of the utility model meets the conditions of eligibility for protection pursuant to Section 1 of Act no. No. 478/1992 Coll.

CZ 25368 Ul

Composite wood-concrete composite ceiling beam

Technical field

The technical solution is in the construction industry and concerns composite materials, specifically wood-concrete beams.

BACKGROUND OF THE INVENTION

It is used in many ways for joining wood and concrete. One is joining by means of coupling mandrels, for example, a wooden beam in two parts connected by a steel plate with double-sided darkness is described in PUV 23582. The slab protrudes above the beam and is also used for coupling with a concrete slab. In EP 0832336 a special coupling means based on a large coupling darkness extended by a steel sheet with less darkness is described and in WO 03021042 a construction system consisting of a wooden board and a wooden (steel, concrete) beam is described. The connection is made by a coupling pin placed in a circular opening in the plate. The hole is injected. In FR 2584758, this is a technology of profiling concrete elements, such as creating cornices, haunches, profiled details in a wall-ceiling joint. Wooden elements are installed in concrete using profiled sheet metal elements. The sheet is connected to the wood by means of a bulldog connection and secured by screws, threaded rods, etc.

Another method is a screw connection where, for example, EP 2216455 describes a coupling element in the form of specially adapted screws for coupling wood composites, DE 19602400 discloses a wood-concrete panel consisting of wooden beams, trapezoidal sheet formwork and a concrete slab. Trapezoidal sheet metal is attached to the beams by means of oblique screws. EP 1947254 discloses a structural system for joining a wood-concrete ceiling structure to a masonry structure. The wood-concrete structure is interconnected by wood interlayer screws. In EP 0037567 it is a technology of renovation of existing structures. The joining of wooden ceiling beams to the concrete slab is realized by discrete joints, ie screws and threaded rods.

A wood-reinforced composite interlayer system is also described in US 2008016803 and DE 10351989.

Others include, for example, the system of WO 2009071832, which describes a wood-concrete system with at least two wooden ribs. The top plate is made of high-quality fiber concrete and the interlocking is carried out by means of an adhesive interlayer. FR 2751355 describes the connection of a concrete floor and a wooden frame. The connection system is designed for reconstructions. EP 2072705 describes a wood-reinforced concrete structure consisting of a load-bearing timber (steel, concrete) element with a bottom concrete layer with an inlet or outlet pipe and a top cover layer; connected by a steel plate protruding up to the top of the concrete slab and DE 202006015693 describes a wood-concrete structure consisting of a concrete slab and bearing timber beams. The connection is made by an element inserted into the concrete slab and a longitudinal groove in the beam. The joint is sealed with concrete. IT 0742323 describes the point connection of wood and concrete cross-section. The anchoring of the connecting element is mechanical, the element is metal and it is not intended for gluing or stretching of reinforcement.

There are also systems without couplings. E.g. EP 2243891 discloses a wood-concrete slab whose lower part is formed by horizontal and vertical planks together forming lost formwork for the upper concrete part.

The last method is joining by means of a bar. E.g. PUV 22590 describes the static reinforcement of existing timber frame structures. The coupling element is a metal shear bar with holes. WO 94/11589 describes a material and shape different from the present invention and the application within the composite cross-section is different. The bar is not intended for gluing, it is mechanically anchored into the wooden part of the composite cross-section and it is not used for stretching the reinforcement. In DE 650-99 a strip is described which has a shape in the part extending above the surface of the wood as "play". Everything else, including the glued joint, functions as a fuse, the system is unnecessarily complex, cannot be calculated and therefore not even designed.

The closest prior art is apparently document PUV 19873 describing the technology of joining a wooden ceiling frame and reinforced concrete slab by means of a glued coupler steel strip. It differs from the present technical solution in the geometry and material composition of the coupler and in the geometry of the groove for bonding the coupler. The application of the beam according to PUV 19873 in practice has shown that, unfortunately, it does not meet the essential requirement for this product, namely reliability under stress of increased humidity. The present technical solution is in comparison with PUV 19873 a construction with higher durability and reliability and with higher comfort of application.

The essence of the technical solution

The composite wood-concrete composite ceiling beam consists of a wooden part and a reinforced concrete part. The wooden part is made of glued laminated timber and its dimensions are designed based on the load and span requirements of the final structure in which the beam will be used. In the upper face of the wooden part of the profile, in its axis, a continuous groove of special dimensions and geometry is milled. Into the groove is glued a strip of high-strength water-resistant wooden plywood without additional surface treatment. The bar is made as an infinite element, its length depends on the length of the beam (construction). The geometry of the groove and the bar and the material characteristics of the individual components guarantee an increase in the durability and reliability of the entire coupling system, which in this case is ensured in particular by gluing the coupling bar into the groove in the upper face of the wooden section. In the upper part of the molding (a part that is not glued into the groove), circular openings are created through which the reinforced concrete slab reinforcement is used to complete the ceiling construction in which the composite wood-reinforced composite ceiling beam will be used. The bottom part of the bar is designed for gluing into the groove. The bar tip is provided with a double-sided blade. Shallow side grooves are milled at the sides of the bar to increase the reliability of the glued joint. Before application, the surface of the molding is free of dirt, roughened and possibly moistened with water vapor so that the maximum surface moisture is 20%. Moistening is performed only if the relative humidity is less than 50%. The groove is also cleaned or moistened by briefly applying water vapor again so that the maximum surface moisture is 20%. Moistening is performed only if the relative humidity is less than 50%. This is followed by the application of the adhesive according to the adhesive manufacturer's technological process. Adhesive is applied to the narrower part of the groove. Further, a bar is inserted into the groove so that the double-sided blade gradually pushes the liquid adhesive into the lateral shallow longitudinal grooves while simultaneously filling the space between the groove wall and the surface of the bar. The remainder of the adhesive is extruded into the wider (upper) part of the groove. In the open gluing time (according to the technical specification of the adhesive) the filling of the adhesive volume to the wider (upper) part of the groove is applied by a suitable applicator. After curing of the adhesive (according to the technical specification of the adhesive manufacturer) the construction is completed, ie. openings in the bar are drawn through reinforcement, formwork, reinforcement assembly, concreting, formwork, finishing of wooden and concrete parts of the structure, etc.

The coupling bar has a thickness (width) of 2 to 8.5 mm and a height of 87.5 to 300 mm. At the lower end it is provided with a double-sided blade 5 to 15 mm high. Round holes 14 to 42 mm in diameter are equally spaced in the bar in such a way that their center centers from the top edge of the bar are 14 to 28 mm and the distance between the centers of the holes themselves is 45 to 180 mm. Shallow side grooves with a length of 100 to 400 mm and a height of 2.5 to 10 mm are milled on the sides of the bar. The lateral grooves are placed in two rows one above the other so that the grooves in the bottom row are located 10 to 30 mm from the top edge of the double-sided blade and the distance between the top edge of the groove in the bottom row and the bottom edge of the groove in the top row is 25 to 100 mm . The individual grooves in each row are spaced in the longitudinal direction at a distance of 75 to 300 mm, with the grooves in the upper row offset from the grooves in the lower row by a distance of 12.5 to 50 mm.

The groove has a width of 3 to 11.5 mm in the narrower (lower) and a width of 6.5 to 13 mm in the wider (upper). The lower (narrower) groove has a height from 42.5 to 170 mm and the upper (wider) groove has a height from 25 to 100 mm.

-2EN 25368 Ul

The composite wood-beam according to the technical solution excels in high load-bearing capacity, compared to competing products with higher durability and reliability, higher utility standards, ie it has more favorable environmental characteristics, lower weight and higher comfort of application.

Clarification of the figures in the drawings

The technical solution is explained in more detail with the help of drawings, where Figure 1 shows an overall view of a composite wood-concrete beam, Figure 2 shows the geometry of the coupling bar in two views and Figure 3 shows the geometry of the groove.

Example of technical solution implementation

The composite wood-concrete composite ceiling beam according to Figures 1, 2 and 3 consists of a wooden part I and a reinforced concrete part 2. The wooden part 1 is made of glued laminated timber and has a width of 160 mm and a height of 290 mm. In the upper face of the wooden part and the profile, in its axis, a continuous groove 4 with a width of 6 mm in the narrower (lower) and 9 mm in the wider (upper) part is milled in a joinery manner. The groove 4 has a height of 85 mm in the lower part and 50 mm in the upper part. A groove 4 of high-strength water-resistant plywood is glued into the groove 4 without additional surface treatment. The strip 3 is made as an infinite element, its length depends on the length of the beam (structure), its thickness is 4 mm and its height is 175 mm. In the upper part of the slat 3 (a part that is not glued into the groove 4), circular openings 5 are formed which, when completing the ceiling construction in which the composite wood-composite composite ceiling beam will be used, the reinforced reinforced concrete slab 2. the spacing of their centers from the upper edge of the strip 3 is 21 mm and the distance between the centers of the holes 5 themselves is 90 mm. The diameter of the circular holes 5 is 28 mm. The lower part of the strip 3 is intended for gluing into the groove 4. The tip of the strip 3 is provided with a two-sided blade 6 with a height of 10 mm. Shallow side grooves 7 with a length of 200 mm and a height of 5 mm are milled on the sides of the bar 3, which serve to increase the reliability of the glued joint. The side grooves 7 are arranged in two rows one above the other so that the grooves 7 in the lower row are located 20 mm from the upper edge of the double-sided blade 6 and the distance between the upper edge of the groove 7 in the lower row and the lower edge of the groove 7 mm. The individual grooves 7 in each row are spaced 150 mm in the longitudinal direction, with the grooves 2 in the upper row being offset by 25 mm in the longitudinal direction relative to the grooves 7 in the lower row. Before application, the surface of the strip 3 is free of dirt, roughened and possibly moistened with water vapor. The groove 4 is also cleaned or moistened by short-term exposure to water vapor. Thereafter, an adhesive is applied to the narrower part of the groove 4 by volume. Further, the strip 3 is inserted into the groove 4 so that the double-sided blade 6 gradually pushes the liquid adhesive into the lateral shallow longitudinal grooves 7 and at the same time the adhesive fills the space between the wall of the groove 4 and the surface of the strip 3. 4. In the open bonding time, apply a volume of adhesive to the wider (upper) part of the groove 4 with a suitable applicator. After the adhesive has cured, the construction is completed, ie. openings 5 in the bar 3 stretch the reinforcement, formwork, reinforcement assembly, concreting, formwork, final surface treatment of wooden and concrete 2 parts of the structure, etc.

Industrial applicability

Composite wood-concrete beam according to the technical solution can be used in wood-concrete ceiling structures in building construction, especially in multi-storey buildings, resp. in such buildings where it is necessary to ensure the spatial rigidity of the building in the plane of the ceiling structure.

Claims (8)

PROTECTION REQUIREMENTS A composite wood-concrete composite ceiling beam composed of a wood part and a reinforced concrete part, characterized in that a continuous groove (4) is milled in the upper face of the wooden part (1), in its axis, into which the coupling strip (3) is glued. Composite wood-concrete composite ceiling beam composed of a wood part and a reinforced concrete part according to claim 1, characterized in that in the upper part of the strip (3) which is not glued into the groove (4), circular openings (5) are formed through which it extends. reinforcement of reinforced concrete slabs (2). A composite wood-concrete composite ceiling beam composed of a wood part and a reinforced concrete part according to claim 1 or 2, characterized in that the wood part (1) is made of glued laminated timber and the molding (3) is made of high-strength water-resistant wood plywood. Composite wood-concrete composite ceiling beam composed of a wood part and a reinforced concrete part according to any one of the preceding claims, characterized in that the coupling strip (3) has a thickness of 2 mm to 8.5 mm, a height of 87.5 mm to 300 mm. Composite wood-composite composite ceiling beam composed of a wood part and a reinforced concrete part according to any one of the preceding claims, characterized in that the coupling strip (3) is provided at the lower end with a two-sided cutting edge (6) 5 mm to 15 mm high. Composite wood-composite composite ceiling beam composed of a wood part and a reinforced concrete part according to any one of the preceding claims, characterized in that the circular openings (5) in the coupling bar (3) are evenly spaced and have a diameter between 14 mm to 42 mm. their centers from the upper edge of the strip (3) are 14 mm to 28 mm and the distance between the centers of the holes (5) themselves is 45 to 180 mm. A composite wood-concrete composite ceiling beam composed of a wood part and a reinforced concrete part according to any one of the preceding claims, characterized in that shallow side grooves (7) with a length of 100 mm to 400 mm are milled on the sides of the coupling strip (3). height from 2.5 mm to 10 mm and are placed in two rows one above the other so that the grooves (7) in the bottom row are located 10 mm to 30 mm from the upper edge of the double-sided blade (6), distance between the upper edge of the groove (7) in the lower row and the lower edge of the groove (7) in the upper row is 25 mm to 100 mm and the individual grooves (7) in each row are spaced from 75 mm to 300 mm apart in the longitudinal direction; ) in the upper row they are offset by 12.5 to 50 mm in the longitudinal direction compared to the grooves (7) in the lower row. Composite wood-composite composite ceiling beam composed of a wood part and a reinforced concrete part according to any one of the preceding claims, characterized in that the groove (4) has a width of 3 mm to 11.5 mm in the narrower part and a width of 6 in the wider part. 5 mm to 13 mm, the narrower part of the groove (4) has a height from 42.5 mm to 170 mm and its wider part has a height from 25 to 100 mm.