NL2002541C2 - PREFABRICATED CONCRETE FLOOR ELEMENT OF THE "WIDE PLATE FLOOR" TYPE. - Google Patents

Description

PREFABRICATED CONCRETE FLOOR ELEMENT OF THE "WIDE PLATE FLOOR" TYPE

The invention relates to a prefabricated concrete floor element of the "wide slab floor" type provided with an internal reinforcement which extends at least substantially parallel to a surface of the floor element.

Such a floor element, which in practice is also referred to by the term "wide plate floor", is generally known. The known wide slab floor comprises an interior, that is to say a reinforcement cast in the concrete, which may or may not be prestressed. The internal reinforcement is, for example, a spot-welded reinforcement mesh and / or reinforcement bars and / or prestressed strands. The wide slab floor is furthermore equipped with lattice girders extending over its entire or partial length. The lattice girders are usually three-dimensional lattice girders of reinforcing steel that during prefabrication have only partially collapsed in height direction into the wide slab floor. The lattice girders serve on the one hand to provide the broad slab floor with its strength and rigidity which are required during construction, during transport and during pouring of a layer 25 to be applied thereto (in practice also referred to as "pressure layer") at the construction site . In particular in the case of a non-prestressed wide slab floor with a thickness of 40 - 70 mm, a continuous lattice girder is necessary for the rigidity and strength during hoisting and pouring of the wet pressure layer 30 onto the wide slab. On the other hand, the lattice girders serve as a possible coupling reinforcement between the wide slab floor and a reinforcement of a concrete pressure layer to be applied thereon later in the work. The wide plate floor is therefore a formwork plate for a free-standing floor to be formed, which therefore consists of the wide plate floor and the pressure layer. Optionally, a separate reinforcement is provided in the printing layer. The internal reinforcement in the wide slab floor then forms a lower reinforcement, while the reinforcement in the pressure layer forms an upper reinforcement. As stated, the lattice girders function as a spacer for the top reinforcement in the pressure layer and / or coupling reinforcement between the wide plate floor and the pressure layer. The non-prestressed wide slab floor is hoisted to the lattice girders, while the prestressed wide slab front is optionally provided with separate lifting eyes that are cast therein to enable it to be able to lift the wide slab floor more easily than with the help of its lattice girders, for example from a lorry to a construction site.

It is noted that broad slab floors stacked on top of each other on the truck are transported to the construction site. The wide slab floors are herein stacked on intermediate stacking blocks or on (continuous) lattice girders of underlying wide slab floors. This results in an unstable loading situation, with all the associated dangers. Due to the lattice girders and required stacking blocks, the loading of the truck cannot be fully utilized as a result of height restrictions on the road network and special provisions must be made by means of tires to securely lash and transport the stacks.

It is the object of the invention to improve the state of the art in the sense that wide slab floors are provided with which lorries can be loaded more securely to a lower height, and unloaded, so that no special safety provisions when fitting (for example a fall protection) are necessary, with preferred pre-stressed thin wide slab floors without lattice girders.

To this end, a prefabricated concrete floor element of the "wide slab floor" type has the type according to the invention mentioned in the preamble that at least one loop-shaped hoisting element of a flexible material is arranged in the floor element, the internal reinforcement being formed by a prestressing reinforcement, and wherein the loop-shaped member is wound around the prestressing reinforcement. The invention is based in particular on the insight to provide a wide slab floor without projecting parts, so that such wide slab floors can in principle be stacked on top of each other without stand blocks, for example on a loading floor of a truck. The present wide slab floor is therefore not equipped with prefabricated lattice girders as prefabricated floor element, as is the case with the prior art. Thus, a securely transportable whole of superimposed wide slab floors can be realized without the use of the known high stacking blocks. The flexible material is preferably selected from the group of materials consisting of plastic, rope and metal.

In a preferred embodiment of a prefabricated concrete floor element of the "wide slab floor" type according to the invention, the prestressing reinforcement is provided with several mutually parallel prestressing bars.

The invention also relates to a method for manufacturing a prefabricated concrete floor element of the type "wide slab floor" according to the invention, wherein a reinforcement comprising several, 4 mutually parallel prestressing bars is supplied, wherein several, loop-shaped hoists from a flexible material are subsequently supplied. around pre-stressing bars corresponding thereto, and wherein concrete is subsequently poured into a formwork in which the pre-stressing bars with the loop-shaped hoisting members have been arranged beforehand.

The invention also refers to a method for manufacturing a concrete floor using a prefabricated concrete floor element of the "wide slab floor" type according to the invention, wherein - several prefabricated concrete floor elements of the type "wide slab floor" are supplied; - the floor elements are hoisted on their loop-shaped hoisting elements and whether or not they are laid one by one and / or as a stack on a loading floor of a vehicle, the floor elements being stacked on top of each other with interposed thin spacers; - the floor elements are transported to a construction site; - the floor elements are lifted one by one from the loading floor of the vehicle and installed in a structure; a concrete layer is laid on the floor elements in situ.

Preferably, a reinforcement is applied to the floor elements before the concrete layer is poured. The reinforcement is in particular formed by lattice girders.

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Such lattice girders, preferably with a triangular cross-section, do not then have the function of coupling reinforcement, but serve as spacers for the upper reinforcement in the pressure layer.

The invention will be further elucidated on the basis of figures shown in a drawing, wherein figure 1 shows diagrammatically and in perspective a wide slab floor according to the state of the art, as well as the way in which it is mounted on the work, figure 2 the shows a known manner in which the wide slab floors of Fig. 1 are transported, Fig. 3 shows schematically and in perspective a wide slab floor according to the invention, Fig. 4 relates to the way in which the hoisting loop of flexible material is arranged as an example around the reinforcement.

Figure 1 distinguishes a perspective view of a known wide slab floor consisting of a relatively thin concrete slab 1, in which steel reinforcing bars 2 are arranged. The mutually parallel reinforcing bars 2 extend in the longitudinal direction of the plate 1 and parallel to the surface thereof. As shown, the plate 1 is also provided with partially upwardly protruding, steel lattice girders 3 which may or may not extend over the entire length of the plate 1. The lattice girders 3, which are therefore partially collapsed in the plate 1, each consist of two lower wires 4, an upper wire 5 and transverse wires 6 which are attached to the lower wires 4 and the upper wire 5. The lattice girders 3 therefore have a triangular cross section. The plate 1 6 is placed in the structure on at least 1 intermediate stamp and two supports 7,8, whereafter a concrete layer 9 (in practice also referred to as "printing layer") is poured on it. As shown, the pressure layer 9 comprises a steel mesh reinforcement 10 resting on the lattice girders 3.

Figure 2 shows the way in which the plates 1 are being transported to the construction site today. To this end, the plates 1 are hoisted in particular on their lattice girders 3 on a loading floor 11 of a truck 12, the plates 1 being stacked on top of each other. Stacking blocks 13 are thereby used to prevent an upper plate 1 from resting on the lattice girders 3 of an underlying plate 1. It will be clear that a solid loading situation is very dangerous.

Figure 3 shows a wide board floor according to the invention in perspective. This consists of a relatively thin concrete plate 14, in which mutually parallel reinforcing bars 15 extend in the longitudinal direction of the plate 14 and parallel to the surface thereof. As shown, the plate 14 contains no lattice girders. A few hoisting loops 16 of rope have collapsed in the plate 14, the hoisting loops 16 being connected to corresponding rods 15. The plates 14 from the production track are lifted onto these hoisting loops 16 and may or may not be stacked one by one on the loading floor 11 of the truck 12, in each case with the interposition of very thin spacers 17. This is shown in Figure 4. As soon as the plate 14 is mounted in the structure 30, a printing layer 18 is poured, just as in the prior art. The pressure layer 18 optionally comprises a mesh reinforcement 19.

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The invention is not limited to the exemplary embodiments shown, but also extends to other preferred variants that fall within the scope of the appended claims.

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Claims (7)

1. Prefabricated concrete floor element of the "wide slab floor" type provided with an internal reinforcement 5 extending at least substantially parallel to a surface of the floor element, characterized in that at least one loop-shaped hoisting element of a flexible material is arranged in the floor element, wherein the internal reinforcement is formed by a prestressing reinforcement, and wherein the loop-shaped hoist is wound around the prestressing reinforcement. 2. Prefabricated concrete floor element of the "wide slab floor" type according to claim 1, wherein the flexible material is selected from the group of materials consisting of plastic, rope and metal. 3. Prefabricated concrete floor element of the "wide slab floor" type according to claim 1 or 2, wherein the prestressing reinforcement is provided with several mutually parallel prestressing bars. 4. Method for manufacturing a prefabricated concrete floor element of the "wide slab floor" type according to any one of the preceding claims 1, 2 or 3, wherein a reinforcement comprising several, mutually parallel prestressing bars is supplied, wherein several, loop-shaped hoisting members of a flexible material are subsequently arranged around corresponding prestressing bars, and wherein concrete is subsequently poured into a formwork in which the prestressing bars with the loop-shaped hoisting elements have been arranged beforehand. Method for manufacturing a concrete floor using a prefabricated concrete floor element of the "wide slab floor" type according to one of the preceding claims 1 to 4, wherein - several prefabricated concrete floor elements of the type "wide slab floor" are supplied ; 10. the floor elements are hoisted on their loop-shaped hoisting elements and are laid one by one or as a stack on a loading floor of a vehicle, the floor elements being stacked on top of each other with the interposition of spacers; 15. the floor elements are transported to a construction site; - the floor elements are lifted one by one from the loading floor of the vehicle and installed in a structure; 20. a concrete layer is laid on the floor elements in situ. 6. Method as claimed in claim 5, wherein before the concrete layer is poured a reinforcement is applied to the floor elements. Method according to claim 6, wherein the reinforcement is formed by lattice girders. 30