NO783308L - RISTFULV. - Google Patents

Description

Grid floor.

The invention relates to a slatted floor which includes mutually parallel, longitudinal bars which are held together with transverse bars.

A distinction is usually made between two types of slatted floors. The first type is where there are zigzag-shaped crossbars attached to the longitudinal bars between pairs of adjacent longitudinal bars. The second type is the type to which the present invention relates and which is characterized by the fact that each cross bar extends

over more than two longitudinal bars. Usually, with such slatted floor types, each crossbar will be straight and run parallel to the other crossbars.

In both of the aforementioned slatted floor types, the longitudinal rods are usually designed to absorb the load, while the transverse rods are primarily arranged to hold the longitudinal rods in place in relation to each other. The transverse bars have larger mutual distances than the longitudinal bars. Generally, the longitudinal bars have a rectangular cross-section, with the longest dimension arranged vertically, so that the load-bearing capacity is utilized as best as possible. The longitudinal bars are usually supported by beams or other foundations, while the transverse bars are supported by the longitudinal bars.

It is a requirement for grid floors that the distances or gaps between adjacent bars must be so small that the floor is not dangerous for personnel walking on it and so that the risk of equipment falling through the floor and possibly hitting someone below is as small as possible, but this requirement stands in contrast to the requirement that the floor must have the desired load-bearing capacity with minimal material consumption.

According to the invention, a slatted floor is provided including mutually parallel longitudinal rods which are held together with transverse rods, each transverse rod extending over more than two longitudinal rods, and what characterizes the slatted floor according to the invention is that intermediate elements are arranged in the gaps between adjacent longitudinal rods, as each such intermediate element is rectilinear, is parallel to the longitudinal bars and has a cross-sectional area which is smaller than the cross-sectional area of each of the longitudinal bars.

Preferably, the intermediate members are arranged so that they lie under the crossbars and are only supported directly by them. The longitudinal bars are directly supported on foundations and support the crossbars.

According to the invention, a method for producing such a grid floor is also provided, and the method is characterized by longitudinal rods being arranged parallel to each other and at mutual distances with intermediate gaps, in which a respective elongated element is placed which runs parallel to the longitudinal rods, in that the cross-sectional area of each such elongate element is smaller than the cross-sectional area of each length bar, and in that cross bars are brought into contact with the length bars and attached to these, and in that the cross bars are attached to the elongate elements either before or at the same time as the attachment to the length bars.

The crossbars can be attached to the elongated elements before some

of these are brought into place between the length bars. The slatted floor can therefore be constructed in such a way that the longitudinal bars are attached to a latticework that includes the oblong elements and the crossbars.

The invention shall be described in more detail with reference to the drawings where Fig. 1 shows a plan of a slatted floor according to the invention,

Fig. 2 shows a section through the grating floor in fig. 1, and

Fig. 3 shows how the grid floor in fig. 1 can be produced. Grate floor panels are usually produced which are then transported to the place of use where the slat floor is built up, as the slat floor panels are laid side by side on suitable storage or foundations. The expression "slatted floor" used here is intended to include both such slatted floor panels and a slatted floor composed of such slatted floor panels.

The fields are usually rectangular, although* naturally you can produce fields with different shapes, for example so that they can fit around elements that pass through the floor.

In fig. 1 shows a section of a grid floor field. The field includes several longitudinal bars lo (longitudinal pliers). which are connected to each other by means of transverse rods 11 (cross rods). The length bars. are straight and have a rectangular cross-section with the longest dimension positioned vertically when the field is positioned horizontally. When the floor is in use, the end sections of the length bars will rest on suitable foundations, e.g. beams that are supported by columns, pillars or by walls in a building, etc. Further storage or supports for the longitudinal bars can of course be arranged between the end sections of the longitudinal bars as required.

Each crossbar 11 extends over all longitudinal bars lo in the field and. lies in a notch designed in the upper edge sides of the length bars. The crossbars are attached to the longitudinal bars by fusion. The transverse bars are supported exclusively by the longitudinal bars. The downward load on a cross bar when using the floor will be transferred to the floor foundations through the longitudinal bars, lo.

When the floor is in use, the edges of the longitudinal bars adjacent to the crossbars 11 will be the upper edges of the longitudinal bars. Intermediate elements 12 are arranged between the longitudinal bars and below the transverse bars. The intermediate elements lie below the upper edges of the longitudinal bars and usually do not absorb any load during use of the floor. The cross-sectional area of each intermediate element 12

is several times smaller than the cross-sectional area of each longitudinal bar lo. For example, a longitudinal rod can have a width of 5 mm and a depth of 30 mm, while an intermediate element is formed by a round rod or wire with a diameter of approx. 7 mm. Alternatively, the intermediate elements can be formed from wire or rods with a square cross-section, as the elements are then twisted around the longitudinal axis and have a cross-sectional area that corresponds to the cross-sectional area of a round wire. In the particular numerical example that is being discussed here, the mutual distance or the division between the longitudinal rods will be 30 mm and in each gap between adjacent longitudinal rods a simple intermediate element is arranged, so that the smaller gaps between each intermediate element and the adjacent longitudinal rod have a width of approx. 9 mm

in the design example, the longitudinal bars are lo, the transverse bars. 11 and the intermediate elements 12 are all rectilinear and the intermediate elements lie parallel to the longitudinal rods and centrally in the gaps between adjacent longitudinal rods, while the transverse rods run at right angles to the longitudinal rods and the intermediate elements. The crossbars can have a mainly square cross-section, but twisted about their respective longitudinal axes.

Fig. 3 shows how the grid floor can be produced. The necessary number of longitudinal bars and intermediate elements 12 are held in place, in their respective positions, by means of a jig 13.

Here, the jig has the form of a deck or a platform which in its upper surface has grooves 14 for the longitudinal rods lo and grooves 15 for the intermediate elements 12. The depth of the grooves 14 is less than the depth of the longitudinal rods, i.e. the longest cross-sectional dimension of the longitudinal rods. The difference roughly corresponds to the depth of the crossbars 11, like this

that the longitudinal bars protrude approximately correspondingly upwards from the jig's upper surface. The depth of the grooves 15 is slightly less, usually 10% less than the thickness of the intermediate elements. so that these elements only slightly protrude above the surface of the jig. The jig 13 only extends along part of the length of the longitudinal bars and the intermediate elements, for example a distance corresponding to between one and two times the division between the transverse bars 11.

The device used for the production of the floor further includes a pair of electrodes 16 and 17 which are arranged above the jig 13. Each electrode has a length that roughly corresponds to the length of the jig so that the electrodes extend over the entire width of the floor or field being produced. The electrodes have a distance between them in the longitudinal direction of the longitudinal bars adapted so that the respective longitudinal center lines of the electrodes have a distance between them which corresponds to the division for the cross bars 11. The electrodes are mounted by means of fasteners not shown so that they can be moved towards and from

the jig 13.

With the electrodes 16 and 17 lifted clear of the length bars and the intermediate elements 12 in the jig 13, two cross bars 11 are placed in place over the upper edge sides of the length bars, directly under the respective electrodes. The electrodes are then lowered into contact with the respective crossbars and an electric current is then led from the electrode 16 through the underlying crossbar, through the longitudinal bars lo and via the other crossbar to the electrode 17. This results in a resistance heating of the longitudinal bars in the places, where they cross the crossbars. The cross bars are pressed downwards by the electrodes and form notches in the upper edge sides of the longitudinal bars. When the notches have become so deep that they roughly correspond to the depth of the crossbars, the crossbars will come into contact with the intermediate

the elements 12 and also through these an electric current passes so that you get a heating in the places where the crossbars

crosses, the intermediate elements. In this way, the cross bars are welded firmly both to the longitudinal bars and to the intermediate elements. The downward movement of the cross bars ends before they reach the jig 13.

When a pair of crossbars have been connected to the longitudinal bars and the intermediate elements, the electrodes 16 and 17 are pulled up again. The longitudinal bars and intermediate elements are moved a distance equal to twice the division of the transverse bars and a further pair of transverse bars are connected to the longitudinal bars.

With an alternative production method, a lattice work is first formed which includes the cross bars 11 and , the intermediate elements 12. The cross bars and the intermediate elements are placed in the relative positions they should have in the finished floor and in particular it applies that the intermediate elements are arranged with a division that is equal to the division that the longitudinal bars must have. The intermediate elements are then attached to the crossbars by means of welding.

A number of mutually parallel longitudinal rods are then brought into contact with the gridwork and positioned correctly in relation to this, so that the same pattern as in the finished floor is obtained. The crossbars are then attached to the longitudinal bars using a welding methodology of the same type as that described in connection with Figure 3.

With both of the aforementioned methods, the floor or field can be finished by arranging extra rods at the ends of the longitudinal rods and connecting them to each other.

Claims (8)

1. Slatted floor including mutually parallel longitudinal rods which are held together with transverse rods, each transverse rod extending over more than two longitudinal rods, characterized in that intermediate elements (12)" are arranged in the gaps between adjacent longitudinal rods (lo), each such intermediate element is rectilinear, is parallel to the longitudinal bars and has a cross-sectional area that is smaller than the cross-sectional area of each of the longitudinal bars. 2. Grid floor according to claim 1, karx acterized by the intermediate elements (12). only carried by the crossbars 11. 3. Grid floor according to claim 1 or 2, characterized in that the intermediate elements (12) 1 are arranged at a distance from and between imaginary planes through the edges of the longitudinal bars. 4. Grid floor according to claim 3, characterized in that the intermediate elements (12). lies under the crossbars (11) in the finished floor. 5. Slatted floor according to one of the preceding claims, characterized in that the intermediate elements (12) are formed of rods or wire with an essentially circular cross-section. 6. Method for producing a slatted floor according to claim 1, characterized in that longitudinal bars are arranged parallel to each other and at mutual distances and that in the intermediate gaps one is placed respectively of long element parallel to the longitudinal rods, the cross-sectional area of each such intermediate element being smaller than the cross-sectional area of each of the longitudinal rods, that transverse rods are brought into contact with the longitudinal rods and attached to them, and that the crossbars are attached to the elongated elements either before or at the same time as the attachment to the longitudinal bars. 7. Method according to claim 6, characterized in that the longitudinal bars are supported with corresponding edges in one and the same plane, that the elongated elements are supported in respective positions at a distance from the said plane, that the transverse bars are laid on the corresponding edges to length -bars and then moved in relation to the longitudinal bars in a direction towards the elongated elements, thereby deforming the longitudinal bars and establishing a contact between the transverse bars and the elongated elements. 8. Method according to claim 6, characterized in that a latticework is produced by arranging the crossbars parallel to each other and at intersections with the oblong elements, and that each crossbar is attached to each of the oblong elements, and that the longitudinal bars are then brought to contact with the crossbars and attach to these at the contact points.