EP4326953A1

EP4326953A1 - Horizontal floor made up of a load-bearing structure and floor panels laid thereon

Info

Publication number: EP4326953A1
Application number: EP22722500.0A
Authority: EP
Inventors: Jan-Willem Frederiks
Original assignee: Nedcon BV
Current assignee: Nedcon BV
Priority date: 2021-04-20
Filing date: 2022-04-12
Publication date: 2024-02-28
Also published as: US20240209620A1; WO2022223375A4; WO2022223375A1; DE102021109959A1

Abstract

A horizontal floor consists of a load-bearing structure and panels (7), which are laid thereon and together form a floor surface, wherein the load-bearing structure is made up of at least one main profile (1), which is fastened on vertical supports, and secondary profiles (2), which are arranged transversely in relation to the main profile (1), are connected at their end to the main profile (1) and on which the panels (7) rest by way of their underside (7A). In order for the load-bearing structure of a horizontal floor to be developed further such that all the forces acting horizontally on the floor are optimally absorbed by the load-bearing structure, a connecting element (20) is provided, this connecting element being made up in one piece of a first fastening edge (21), a second fastening edge (22), which is parallel to the first fastening edge, and a central portion (25) between the two fastening edges (21, 22). The first fastening edge (21) is at least indirectly supported on the main profile (1) and connected to it. The second fastening edge (22) is supported on the underside (7A) of one of the panels (7) and connected to this panel (7).

Description

Horizontal floor made of a traa construction and floor panels bonded to it

The invention relates to a horizontal floor consisting of a supporting structure and plates laid on top of it, jointly forming a floor area, with the supporting structure being composed of at least one main profile fixed to vertical supports and secondary profiles arranged transversely to the main profile, which are connected at their end to the main profile are and on which the panels rest with their underside.

In the course of the strong growth in the logistics industry, ever larger interim storage facilities with optimized space are required with support structures in the form of shelves for, for example, Euro pallets. When designing such stores, the aim is to create as much storage capacity as possible with the smallest possible space requirement. In order to keep costs down, the supporting structures often consist of profiles and cold-formed metal sheets that are assembled in a modular manner to form the supporting structure. The aim is also to reduce the number of vertical supports that reduce the actually usable storage area. However, in order to ensure the structural integrity of the supporting structure, it is necessary to reinforce the horizontal beam profiles. However, the frequently used, cold-formed beam profiles do not have high strength in all load directions, which sometimes makes it necessary to use solid double T-beams for the main beams, which were produced in a hot-forming process. Auxiliary profiles are attached to these massively designed main profiles, arranged transversely to them. The latter are made from inexpensive, cold-formed sheet metal, often have an open, i. H. not closed profile cross-section, and have on their upper side a sufficiently large contact surface on which the base plates of the supporting structure are supported, the base plates being connected to the secondary profile by vertical screw connections, or alternatively riveted to it.

However, the secondary profiles, which are only cold-rolled and often have an open profile cross-section, are not suitable for absorbing all the loads acting on the secondary profiles in the horizontal direction equally well. Disadvantages are above all strong Scherbe loads, namely horizontal forces acting transversely to the longitudinal extent of the secondary profiles. A disadvantage is their influence, especially in the area of attachment of the secondary profile to the main profile. Here adverse shear stresses z. B. occur when heavy goods are moved horizontally on the bolted to the secondary profiles plates.

The task of the present invention is to further develop the support structure of a horizontal floor by constructive measures in such a way that all forces acting horizontally on the floor are optimally absorbed by the support structure.

To solve the problem, a horizontal floor with the features of patent claim 1 is proposed.

Accordingly, a connecting element is proposed in particular, which is composed in one piece of a first fastening edge, a second fastening edge parallel to the first fastening edge and a middle section between the two fastening edges. The first fastening edge is, at least indirectly, supported on the main profile and connected to it. The second mounting edge is supported on the underside of one of the panels and connected to that panel.

With the horizontal floor according to the invention a support structure for a Horizon talboden is created, which is characterized by a high resistance to horizontal loading loads in several horizontal directions.

The additional connecting elements create an additional connecting structure between the plates and the supporting structure, which improves the resilience and resistance of the horizontal floor compared to the horizontal floors or supporting structures known from the art.

The plates rest on the secondary profiles and are preferably connected to them by verti le screw connections.

It can be advantageous if the connecting elements are connected and in particular screwed to the main profile and the plate, but not to the secondary profile as well. Because, in order to counteract the horizontal shearing forces, it is sufficient if the connecting elements are supported with their first fastening edge on the main profile and with their second fastening edge on the underside of the plate and are connected to them. This leads to a kind of indirect anchoring of the panels to the main profile in one of the two horizontal directions. When using the main profiles, which are often produced rather roughly by hot rolling, there can be a vertical free space between the main profile and the underside of the plate arranged above the main profile. If the main profiles are connected to the panels via the connecting elements, it is not necessary to process the main profiles in such a way that the panels could lie flat on the main profiles. Rather, the connecting elements and the secondary profiles allow a vertical free space to be maintained above the main profile, as a result of which a flat upper side of the main profile can be dispensed with.

The first fastening edge is preferably designed in the form of a strip and is supported and fastened to a vertical profile section of the main profile. This measure enables simple assembly of the connecting element on the main profile, since lateral accessibility is also possible. In addition, a straightening of the main profile is unnecessary due to the lateral attachment of the connec tion element to the main profile. Furthermore, the installation space required for the connection is kept small by the lateral attachment of the connecting element.

The ends of the secondary profiles are preferably connected to the main profile via a connecting element, the connecting element being fastened to the secondary profile with a connecting area and to the main profile with a connecting flange at right angles to the connecting area. In other words, the connection element represents the link between the profile end of the secondary profile and the main profile.

To ensure that the installation effort is not significantly increased by the connecting element as an additional component, the first fastening edge can be supported on the main profile only indirectly, namely with the connection flange being interposed. The first fastening edge can thus be fixed together with the connection flange of the connection element using the same fastening means, preferably screwing or riveting. It is also conceivable that a bolt is welded to the vertical section of the main profile, with the connection flange and the first fastening edge being screwed to this bolt.

The connection between the first fastening edge and the main profile is preferably made up of at least two screw connections spaced apart from one another in the longitudinal direction of the fastening edge, the distance between which is at least 50% and preferably at least 75% of the length of the first fastening edge. The screw connections are therefore more likely to be arranged in the end areas of the strip, so that the connecting element is fixed at least via its end areas to the main profile or to the main flange. is laid. In order to maximize the moment of resistance against shearing forces, which is increased by the connecting element, it is necessary to make the connecting areas of the first fastening area as long as possible in relation to the overall length of the connecting element and the length of the second fastening area.

The second fastening edge is also designed in the form of a strip. It is supported on and connected to the underside of the plate forming the floor surface. It can be supported with a wide ren part of its length on the underside of another plate and so be connected to the water other plate.

The two fastening edges of the connecting element are designed as flat strips with the main extension parallel to the main profile and transverse to the secondary profiles.

The middle section of the connecting element is preferably composed of two subsections connected along a bending line, with the bending line extending parallel to the two fastening edges, and thus also parallel to the main profile.

The at least one main profile is z. B. a double T-beam made of hot-rolled steel, as this is particularly suitable for absorbing not only vertical but also horizontal forces and loads and deriving them from the vertical supports of the supporting structure.

The main profiles are therefore preferably steel carriers produced in a hot-rolling process. At the upper and lower end of their vertical profile section, these have horizontal profile legs. In order to fasten the first fastening edge of the connecting element to the vertical profile section of the steel beam and the second fastening section to the plates, it is necessary to connect the two fastening edges by a section that runs under the upper horizontal profile leg of the beam.

The sections mentioned are a horizontal and a vertical section, with the sections preferably extending at right angles to one another along the bending line and with each section being connected to the respective fastening edge by a further bending line. In particular, the fastening edges are arranged at right angles to the sections. This step-like design of the connecting element ensures a stiffening of the connecting element itself and, after its assembly, good stiffening against horizontal shear loads, namely horizontal forces acting transversely to the longitudinal extent of the secondary profiles. The connecting element is preferably a sheet metal deformed by bending processes, the starting sheet metal being rectangular or trapezoidal. The manufacture of the connec tion element in such a method is inexpensive.

Further measures are explained in more detail below together with the description of a preferred exemplary embodiment with reference to the figures. It shows:

1 shows a perspective view of a partial area of a support structure made of main and secondary profiles and the panels installed thereon via connecting elements;

Figure 2 is a sectional view taken across the main profile of the supporting structure; and

3 is a sectional view running transversely to the secondary profiles.

Figure 1 shows a perspective view of a part of a horizontal floor used in the field of warehouse logistics, consisting of a supporting structure and panels 7 laid on it, which together form a flat floor surface.

The support structure is composed of vertical supports (not shown), main profiles 1 attached thereto, and secondary profiles 2 arranged transversely to the main profiles 1 and attached laterally to the main profiles. All main profiles 1 and secondary profiles 2 extend horizontally.

In the space between each two secondary profiles 2, a connecting element 20 is attached to the main profile 1 additional Lich. The secondary profiles 2 and the connecting element 20 each form with their upper sides a support for the underside 7A of the panel 7 or panels 7.

The ends of the secondary profiles 2 are not connected directly to the main profile 1, but are each connected to the main profile 1 via a connecting element 3. For this purpose, the connection element 3 is fastened to the secondary profile 2 with a connection area 4A and to the main profile 2 with a connection flange 4B that is perpendicular to the connection area 4A. To connect the secondary profile 2 to the connection area 4a of the connecting element 3, it is also conceivable that both components have a complementary contour in order to create a positive and non-positive connection when plugged into one another. In principle, a screw connection or riveting or a combination of screw connection or riveting and form fit between connection element 3 and secondary profile 2 is possible.

The connecting element 20 is advantageous with regard to the transmission of shear stresses, namely horizontal forces acting transversely to the longitudinal extent of the secondary profiles 2, to the supporting structure. Their influence is disadvantageous above all in the area of the connection of the secondary profiles 2 with the main profile 1, specifically in the area of the connecting elements 3. Disadvantageous loading conditions can occur in particular when heavy goods are moved on the plates 7 screwed to the secondary profiles 2. Because the secondary profiles 2 are better able to absorb horizontal forces in the direction of their own longitudinal extent than horizontal forces transverse to their own longitudinal extent.

The individual connecting element 20 is composed of a first fastening edge 21, a second fastening edge 22 parallel to the first fastening edge 21 and a middle section 25 between the two fastening edges 21, 22. The first fastening edge 21 is here with the connecting flange 4B interposed the verti cal profile section of the main profile 1 at least indirectly supported and screwed to this. The first fastening edge 21, the connection flange 4B and the main profile 1 thus form a common connection area.

Although the connecting element 20 is connected to the main profile 1 and to at least one plate 7, it is not connected to the secondary profile 2. Consequently, a force acting on the plate 7 transversely to the longitudinal extension of the secondary profile 2 is transmitted via the connecting element 20 to the solid and stable main profile 1 and not primarily to the secondary profiles 2. This leads to a relief of the secondary profiles 2, especially in the area of the connection elements 3.

The fastening edge 22 of the connecting element 20 and the secondary profiles 2 reach higher than the top of the main profile, resulting in a vertical clearance 16 between the main profile 1 and the bottom 7A of the panel 7 arranged above the main profile 1.

In order to be able to change the vertical free space 16, the connecting element 3 can be designed with a multiplicity of bores 6 arranged vertically one above the other on the connecting flange 4B. The connecting element 3 can be fastened to the vertical profile section of the main profile 1 in various vertical positions due to the many bores 6 . The connection between the first fastening edge 21 and the main profile 1 is preferably made by means of two screws 17 which are clearly spaced apart from one another in the longitudinal direction of the fastening edge 21 and which engage in bores in the vertical profile section of the main profile 1, and the distance between them is at least 50% and preferably at least 75% % of the total length of the first attachment edge is 21%. It is conceivable that more than two screws 17 and associated bores are arranged along the first fastening edge 21 and the main profile 1 and connect them to one another.

Of course, additional secondary profiles 2 and connecting elements 20 can also be attached to the main profile 1 from the other side, ie from the left in FIG.

The second fastening edge 22 of the connecting element 20 is supported on the underside 7A of the plate 7 and is connected to the plate 7 via rivets or screws 18 . The plate 7 rests on the secondary profiles 2 and is fastened to it by means of screws 18 or rivets. To a sliding z. B. to facilitate a charge on the floor panels, Einsenkun conditions are provided on top of the plates 7, in which the screws or rivet heads are fully sunk constantly.

The main profile 1 is z. B. a steel girder produced in a hot rolling process, more precisely a double T-beam with two horizontal legs running one above the other and parallel to one another and a vertical profile section connecting them. To fasten the first fastening edge 21 to the vertical profile section, the middle section 25 of the connecting element 20 is composed of two partial sections 27, 28 connected at a bending line 33 extending parallel to the two fastening edges 21, 22 (FIG. 2). These sections are a horizontal 27 and a vertical section 28, with the sections 27, 28 preferably extending at right angles to one another along the bending line 33, and with each section 27, 28 preferably being connected to the fastening edge 21, 22 is connected.

In particular, the fastening edges 21, 22 are arranged at right angles to the partial sections 27, 28 adjoining them. This step-like design of the connec tion element 20 ensures good reinforcement of the supporting structure. However, a non-rectangular configuration is also possible, or a different number of stages. Reference character list

1 main profile

2 secondary profile

3 connection element

4A Connection area 4B Connection flange

6 hole

7 plate

7A underside of the plate

8 plate bottom

16 free space

17 screw

18 screw or rivet

20 fastener

21 first attachment edge

22 second fastening edge

25 middle section

27 horizontal section

28 vertical section

31 bending line

32 bending line

33 bending line

Claims

patent claims

1. Horizontal floor consisting of a supporting structure and panels (7) laid on it and jointly forming a floor area, the supporting structure being composed of at least one main profile (1) fastened to vertical supports and secondary profiles (2 ), which are connected at their end to the main profile (1) and on which the plates (7) rest with their underside (7A), characterized by a connecting element (20) which is made in one piece from a first fastening edge (21), a second fastening edge (22) parallel to the first fastening edge and a middle section (25) between the two fastening edges (21, 22), the first fastening edge (21) being supported at least indirectly on the main profile (1) and connected to the sem, and wherein the second attachment edge (22) is supported on the underside (7A) of one of the panels (7) and is connected to this panel (7).

2. Horizontal floor according to claim 1, characterized in that the plates (7) rest on the secondary profiles (2) and are screwed vertically to them.

3. Horizontal floor according to claim 1 or 2, characterized in that the connec tion element (20) is connected to the main profile (1) and to the plate (7), but not to the secondary profile (2).

4. Horizontal floor according to one of the preceding claims, characterized by a vertical free space (16) between the main profile (1) and the underside (7A) of the respective plate (7) arranged above the main profile (1).

5. Horizontal floor according to one of the preceding claims, characterized in that the first fastening edge (21) is connected to a vertical profile section of the main profile (1).

6. Horizontal floor according to one of the preceding claims, characterized in that the ends of the secondary profiles (2) are each connected to the main profile (1) via a connecting element (3), the connecting element (3) having a connecting area (4A). the secondary profile (2), and is fastened to the main profile (1) with a connecting flange (4B) at right angles to the connection area (4A).

7. Horizontal floor according to claim 6, characterized in that the first fastening supply edge (21) is supported with the interposition of the connecting flange (4B) on the main profile (1).

8. Horizontal floor according to one of the preceding claims, characterized in that the connection between the first fastening edge (21) and the main profile (1) is made up of at least two screw connections (17) spaced apart in the longitudinal direction of the fastening edge (21), the Distance is at least 50% and preferably at least 75% of the length of the first attachment edge (21).

9. Horizontal floor according to one of the preceding claims, characterized in that the middle section (25) of the connecting element (20) is composed of two partial sections (27, 28) connected along a bending line (33), the bending line (33) being parallel to the two mounting edges (21, 22) extends.

10. Horizontal floor according to claim 9, characterized in that the partial sections (27, 28) extend at right angles to one another on the bending line (33).

11. Horizontal floor according to claim 9 or 10, characterized in that each partial section (27, 28) is connected to the respective fastening edge (21, 22) at a respective further bending line (31, 32).

12. Horizontal floor according to one of the preceding claims, characterized in that the connecting element (20) is a metal sheet deformed by bending processes.

13. Horizontal floor according to one of the preceding claims, characterized by the formation of the main profile (1) as a steel beam produced in a hot-rolling process.