CZ20002987A3 - Method of making a grate consisting of carrier rods and transverse rods forming together a mesh array of uniform size - Google Patents

Abstract

The grating structures comprise support bars (1) and cross-bars (2) used to form mesh holes (3) with a given length (lN) and given width (bN), and the length and/or width of the mesh holes are then adapted so that all the mesh holes have the same length and/or width.

Description

A method of manufacturing grating from grid and cross bars with uniform mesh size

Technical field

The invention relates to a method of manufacturing grate gratings from support bars and cross bars with predetermined external dimensions, given grate length and grate width, and predetermined nominal mesh dimensions.

BACKGROUND OF THE INVENTION

The gratings are generally formed from substantially parallel mutually support bars and transversely extending substantially mutually parallel cross bars, the support bars and cross bars surrounding the group of meshes of the grid grid.

A large number of practical applications of such gratings are known in the art. These grates are used as stepping grids, covering grids of lighting shafts or similar openings in the pavement, but also in the form of bulky gratings embedded in frames in industrial installations, architectural formations on building envelope or grids for the production of presentation platforms for eg cars and similar purposes .

In particular, the invention relates to those cases in which the grating of a specific embodiment with predetermined external dimensions and with a predetermined nominal mesh size of the grate is used. This applies in particular to gratings for covering openings in the floor intended for shoveling loose materials, such as fertilizers, grains or the like, and having a larger surface area, which are used in industrial facilities, or gratings of prefabricated presentation platforms for exhibiting passenger cars, used mainly at exhibitions and fairs. Such large-area lattice structures are made up of single-walled structures. Individual modular grate elements having a size suitable for handling. In order to simplify production and to facilitate replaceability, individual elements of the same size, the dimensions of which are determined by the overall dimensions of the finished slat construction, are most often used.

Entering the external dimensions as well as the nominal sizes of the individual grate elements in this case often results in these dimensions not harmonizing with each other, but residual meshes are created with the specified external dimensions and also with the nominal grid sizes specified, the dimensions of these residual meshes being different from nominal mesh dimensions of the grate. As a result, asymmetric gratings are produced first, which then give the entire assembled grate structure an asymmetrical and optically disturbing appearance.

The proposal to create grate structures from individual grate elements with residual meshes that are symmetrical at least along their central longitudinal or central transverse axis can be realized by the method of manufacturing grate grates according to EP-0 576 808. This method proposes to deploy residual meshes resulting from the difference between the nominal mesh sizes and the external dimensions of the grating, symmetrically with respect to the median longitudinal axis or the central transverse axis, in order to both produce a symmetrical appearance of the grating and, second, to obtain corner meshes with uniform dimensions. However, despite the symmetrical arrangement of the grate elements, the lattice grate structure formed from these grate modules does not obtain a satisfactory appearance, as in other prior art solutions, since residual meshes having dimensions different from the nominal mesh sizes still exist along the grate structure.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to overcome the drawbacks of the known grate constructions and to provide a method for producing a symmetrical grid with respect to the specified external dimensions and in particular to the 4

44 grate mesh sizes that would allow grating mesh sizes of the same dimensions to be formed.

SUMMARY OF THE INVENTION

This object is solved by a method of manufacturing grate grates from support bars and cross bars with predetermined external dimensions, given grate length and grate width and predetermined nominal grate mesh dimensions, wherein grate mesh lengths and / or grate mesh widths are adapted to values based on nominal lengths and nominal widths such that all mesh grids have the same length and / or width.

In this way, the production of gratings with a uniform grid size, which are symmetrical to their central axes, is ensured and, when assembled into a large-area grid structure, a regular laying pattern with uniform grid sizes is produced. The process according to the invention can be used both in the production of grates and also in the production of grates from pre-measured cross bars and longitudinal support bars which are fed in the form of endless belts unwound from rolls, for example. length. In any case, by means of the method according to the invention, at least one support or transverse bar is saved by means of the correct selection of the mesh sizes of each grate compared to the residual mesh gratings. This results in a reduction in the material consumption for the grate production and thus also in cost savings.

The differences between the nominal mesh size of the grate and the mesh size of the grate, adapted according to the method of the invention, are very small when the matching method is chosen. The observer is unable to detect deviations in size from the original mesh dimensions when the fit option is correctly selected. In particular, the technical assumptions which lead to the determination of the nominal mesh sizes of the grate, such as the dimensions of the fasteners and fasteners associated with the corners of the individual

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999 9 9 99 9 9 9 • 9 · 9 ·· · · 9 9 9 .9 · 9999 999 mesh grates, or the minimum dimensions of items that can still pass through the grid mesh, can also be provided by grid mesh sizes determined from the nominal dimensions of the grating as determined by the method according to the invention.

According to a preferred embodiment of the method according to the invention, the adjusted mesh dimensions of the grate deviate from the predetermined nominal dimensions by at most 10%, preferably at most 5% and particularly preferably at most 3%.

It is also advantageous to take into account the thickness of the support bars and the cross bars when determining the mesh dimensions of the grid.

Taking into account the thickness of the support bars and cross bars can simply be done by defining the grate length and width of the grate by the distance between the center axes of two adjacent transverse and longitudinal bars and then substituting values that are always reduced by one cross bar thickness and support bar thickness. This takes into account the outer cross bars and support bars which are located at the edge of the grate and do not belong to any grate mesh length and width when determining the grate mesh dimensions.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 shows a schematic view of a grate formed by the method of the invention and FIG. 2 shows a schematic view of another example of a grate formed by the method of the invention.

DETAILED DESCRIPTION OF THE INVENTION

An exemplary procedure for determining the mesh length and mesh width, adapted to the needs of the method of the invention and defined as the spacings between the center axes of two adjacent grids.

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4 00 0 0 0 4 '4 of the transverse or support bars with respect to the thickness of the support or distribution bars consist of carrying out the following steps:

a) determining the difference between the length and width of the grate and the thickness of the cross bar and the support bar,

b) determining the ratio of the differences found in step a) to the nominal mesh lengths and mesh widths,

c) determining the number of grate meshes along the length and width of the grate at the ratio determined in step b) or, in the case of ratios represented by less than a number, to the nearest lower integer; and

d) determining the ratio of the length and width values of the grate to the detected number of meshes in step b), wherein the ratio found in step d) determines the length and width of the meshes of the grate.

Alternatively, in step c), if the ratio is obtained in the form of less than a number, the number of meshes may be determined not by adjusting to the nearest lower integer, but to the nearest higher integer.

The grate shown schematically in FIG. 1, consisting of support bars 1 and cross bars 2 which delimit the individual grate eyes 3, is produced by the method according to the invention based on the detection of grate mesh lengths 2 according to the first described alternative.

The base length L of the grate, the width B of the grate and the nominal length 1 _N as well as the nominal width b _{N of the} 3rd grate served as the basis for this production process. For a more accurate representation, they are indicated by dashed lines at intervals of nominal lengths 1 _N and nominal widths —N in the grate shown in Fig. 1. It is obvious that starting from the top edge or right edge of the grate shown in Fig. for the grate meshes 3, they are formed at the left edge or at the bottom edge of the eye with a residual length ÍR 'or with a residue29 ^ 7 ·· ♦ ·

0 »· 0» · _ _ · 0 · ♦ “·» ·. • · * 0 «· '·· -' ·· - ·· width b _R. When using the first alternative, the length of one _M 2 mesh grid determined so that the residual length _R 1 divided by the number n of nominal lengths _1R arranged in the overall length L increases, and this fraction is added to the nominal length of _N _1. This is determined by the grid having mesh the third grid along its length L, which corresponds to the number of nominal lengths _1R arranged sequentially over the entire length L. The length _M 1 mesh the third grid is increased while the length difference dj is greater than the nominal length of one _R wherein the length difference dj corresponds to the nth part of the residual length 1 _R.

Analogous principles apply to the determination of the width b _M meshes 2 of the grate, based on the nominal width b _R and the width B of the grate. Similarly, in this case, a width difference d ^ is created which corresponds to a fraction of the residual width b _R.

The grate shown schematically in FIG. 2 is also a grate of length L and width B, formed of support bars 2 and cross bars 2 which surround the grate eyes 2. In this example, the number of meshes 2 of the grates spaced along the length L of the grate was determined to be the number m of nominal lengths 1 by adding one. To determine the lengths of 1 _M mesh 2 of the grate, the nominal length L _{n is} reduced by the length difference dj, whereby m times the length difference d _L added to the residual length 1 _R corresponds to the 1 _M mesh length thus determined. In this case too, the length difference is only a fraction of the residual length 1 _R.

Analogously to the grating mesh length 1 _{M, the} grating mesh width b _M is also determined, the nominal width being reduced by the width difference d _b .

Of course, it is also possible that the grating mesh width b _M and the grating mesh length 1 _{M are} always determined by one of the two alternatives, namely the grating mesh length 1 _M according to alternative 1 and the grating mesh width M according to alternative 2 or vice versa.

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It will be appreciated that the width difference d1 or length difference dj is the smaller the greater the number of meshes along the width or length of the grating. This means that for grates with a large number of meshes along the grate width B or the grate length L, it is very easy to achieve grate mesh sizes which deviate by about 1% from the nominal dimensions. Thus, the deviations may lie within the specified manufacturing tolerances for the nominal mesh dimensions of the grate.

In order to achieve the minimum deviation of the mesh dimensions from the nominal dimensions, the alternatives mentioned in the previous section are preferably determined in the case of a proportion composed of a number different from an integer by rounding this number to the nearest integer. That is, with a fractional residue of less than 0.5, the nearest lower integer is selected for the number of grate meshes along the length and width of the grate, and in the remaining cases the next higher integer is selected.

The grate produced by the method according to the invention can be provided with additional reinforcing frame elements on its circumferential sides after its assembly, but their function can also be performed directly by the outer circumferential support and cross bars.

The grate length detection alternatives described in the exemplary embodiment are considered to be exemplary and illustrative only in the method of the invention and do not limit the scope of the invention as defined in the main claim 1.

Claims (7)

PATENT CLAIMS A method of manufacturing grid grates from support bars (1) and cross bars (2) with predetermined external dimensions, given grate length and grate width, and predetermined nominal grid dimensions (3), determining grate lengths (3), and / or grid width (3) at which the mesh lengths of the grid grid and / or mesh widths of the grid grid are adjusted to values based on the nominal lengths (1 · _Ν ) and nominal widths (b _N ) such that all mesh (3) The grates have the same length and / or width. Method according to claim 1, characterized in that the adjusted dimensions of the grid meshes (3) deviate from the predetermined nominal dimensions by a maximum of 10%. Method according to claim 1, characterized in that the adjusted dimensions of the grid meshes (3) deviate from the predetermined nominal dimensions by a maximum of 5%. Method according to claim 1, characterized in that the adjusted dimensions of the grid meshes (3) deviate from the predetermined nominal dimensions by a maximum of 3%. Method according to one of Claims 1 to 4, characterized in that the thickness of the support bars (1) and the cross bars (2) are taken into account when determining the mesh dimensions (3). Method according to one of Claims 1 to 5, characterized in that the following are carried out to determine the length and width of the mesh gratings (3) determined by the distance between the central axes of two adjacent cross bars (2) and the supporting bars (2). steps (a) the difference between the length and width of the grate and the thickness2 <shall be determined ··· « • »cross bars (2) and support bars (1), b) determine the ratio of the differences found in step a) to the nominal mesh lengths and widths (3), c) determining the number of mesh grates in the direction of the length and width of the grate from the ratio determined in step b) or, in the case of a ratio represented by less than a number, from the reduction to the nearest lower integer; and d) determining the ratio of the length and width values of the grate to the observed number of meshes (3) in step b), wherein the ratio found in step d) determines the length and width of the meshes (3) of the grid. Method according to one of Claims 1 to 5, characterized in that the following steps are carried out to determine the length and width of the mesh gratings (3) determined by the distance between the central axes of two adjacent cross bars (2) and the support bars (2). a) the difference between the length and width of the grate and the thickness of the cross bars (2) and the supporting bars (1) is determined, b) determine the ratio of the differences found in step a) to the nominal mesh lengths and widths (3), (c) determining the number of mesh slats in the direction of the length and width of the slats from the ratio determined in step b) or, in the case of ratios represented by less than a number, from magnification to the next higher integer; and d) determining the ratio of the length and width values of the grate to the detected number of meshes (3) in step c), the ratio determined in step d) determining the length and width of the meshes (3) of the grid.