AT522567B1 - Lightweight construction element made of wood - Google Patents

Abstract

Lightweight construction element (1) made of wood comprising an essentially flat first layer (2) and a second layer (3) bonded to the first, the second layer (3) forming alternating, oppositely directed first and second folds (4, 5) is gathered, the first folds (4) each having an apex (8) and on both sides of the apex (8) a flank (8, 9) glued to a flank (8, 9) of an adjacent first fold (4) and the second Folds (5) each have an apex (11) and, on both sides of the apex (11), a flank (12, 13) spaced apart from a flank (12, 13) of an adjacent second fold (5), and the second layer (3) is glued to the first layer (2) at the apices (8) of its first folds (4) or at one of its end faces (6, 7) running transversely to the folds (4, 5).

Description

description

The present invention relates to a lightweight construction element made of wood comprising a substantially flat first layer and a second layer glued to the first.

From US 901 334 A various wave forms of a packaging material for sensitive objects are known, which is preferably layered from sheets of paper.

Due to their simple processing, their good mechanical and thermal properties and the environmental compatibility over their entire useful life and beyond, e.g. Used in wood construction and furniture and model carpentry. In addition to solid wood, multi-layer elements have also been used for a long time, e.g. Plywood, laminated wood, veneer strip wood or laminated timber elements. At least two, mostly three or more layers of the same or different wood fiber directions and / or types of wood are glued together, e.g. glued. In this way, components with more homogeneous properties and usually also higher strength are achieved than could be achieved with conventional solid wood elements.

However, such elements are generally not at all, at least not significantly lighter, i.e. lighter than solid wood and therefore not better suited as lightweight construction elements. In order to achieve lightweight construction elements, e.g. known from DE 10 2008 022 805 A1 to produce zigzag or sinusoidal corrugated veneers and to use on both sides, i.e. to glue on the wave crests and the wave troughs with a veneer or a sheet of plywood. In this way, a lighter construction element made of wood can be achieved, which also achieves good flexural and torsional stiffness - albeit lower than that of solid wood - and is more elastically deformable under pressure (“pressure-elastic”); However, under higher pressure this structure fails permanently, since the flanks of the waves, which are inclined to one another due to the zigzag or sinusoidal shape, bend irreversibly. As a result, bending and torsional rigidity also decrease significantly, so that such a lightweight construction element can no longer meet requirements that could previously be met.

From EP 3 037 600 B1 a lightweight wood construction element is known in which several corrugated veneer layers are glued one on top of the other to form a stack, in which stack the corrugated cutting directions of two adjacent glued veneer layers are each at right angles to one another; On two opposite end faces of the corrugated veneer stack, a flat layer of wood is glued to the stack. In this way, lightweight construction elements of great thickness and strength can be produced; a buckling of the waves is hardly likely. However, due to the only slight wave shape that can be achieved when cutting, the ratio of wood-based material to empty space is not very favorable overall, so that only little weight is saved compared to solid wood. If, on the other hand, one were to cut the veneers in a stronger wave shape, each veneer would receive varying strength when cutting due to the density fluctuations in the wood, which are usually visible as annual rings, which significantly and unpredictably affects the overall strength of such a lightweight construction element.

The invention aims to create a lightweight construction element made of wood, which combines high bending and torsional rigidity with compressive elasticity and high compressive strength and is lightweight and flexible in use.

This object is achieved according to the invention with a lightweight element of the type mentioned, which is characterized in that at least one of the first and second layers is made of veneer and the second layer is gathered to alternate, oppositely directed first and second folds , wherein the first folds each have an apex and on both sides of the apex a flank glued to a flank of an adjacent first fold and the second folds each have an apex and on both sides of the apex a flank spaced apart from a flank of an adjacent second fold, and wherein the second Position is glued to the apex of their first folds or on one of their end faces running transversely to the folds with the first layer.

This results in a kink-free, approximately meandering course of the second layer with different radii of curvature of its first and second folds transversely to the folds. The flanks of the first folds, which are glued together, bring high stability, bending and torsional rigidity to the lightweight construction element. At the same time, the compressive elasticity of the second folds, which are movable due to the mutual spacing of their flanks, is high. Buckling of the flanks of the first and second folds under pressure is largely ruled out, since the first folds are supported on one another permanently and the second folds are supported on one another under pressure, which leads to particularly high compressive strength. Veneer is thin and light, easy to manufacture and has high tensile strength (at least in its fiber direction), which leads to a stable lightweight construction element. By choosing the veneer thickness or type of wood, the weight and stability of the lightweight construction element can be flexibly adapted to various requirements and applications over a wide range. The lightweight construction element is particularly lightweight and either as planar or substantially planar, i.e. Slightly curved plate can be produced. It can be combined with lightweight construction elements of the same type - also retrospectively - e.g. in that two lightweight construction elements are glued to one another at their first layers or the second folds of two lightweight construction elements are brought into meshing engagement with one another or glued to one another at their apices; the lightweight construction element can also be further supplemented in one of the ways described below and can therefore be used particularly flexibly.

In a favorable embodiment, one of the first folds has an apex that is widened compared to the other first folds. The fold with the flared apex forms a channel into which other components can be inserted, e.g. Cables, pipes or the like. Depending on your needs. This creates additional possible uses for the lightweight construction element.

A particularly advantageous embodiment is characterized by a third layer which is gathered into alternating, oppositely directed first and second folds, which second folds mesh with the second folds of the second layer, the first folds of the third layer each having one Apex and on both sides of the apex have a flank glued to a flank of an adjacent first fold of the third layer and the second folds of the third layer each have an apex and on both sides of the apex a flank glued to a flank of an adjacent second fold of the second layer, and wherein the second and third layers are spaced from each other at the apices of their first and second folds. As a result, a particularly light, yet flexurally and torsionally stiff lightweight construction element is created, which is also elastic in pressure despite its high compressive strength.

An alternative embodiment comprises a third layer, which is gathered to alternately successive, oppositely directed first and second folds, which second folds mesh with the second folds of the second layer, the first folds of the third layer each having an apex which the vertex of a second fold of the second layer is glued inside the first fold of the third layer, and on both sides of the vertex have a flank glued to a flank of an adjacent first fold of the third layer and the second folds of the third layer each have one inside one first fold of the second layer with the apex glued to the apex and a flank on both sides of the apex, and wherein the second and third layers are spaced apart from one another on the flanks of their first and second pleats. In this way, a lightweight construction element with a particularly high compressive strength is created, which is also particularly resistant to bending and torsion.

It is advantageous if at least one of the first, second and third layers is made of ply wood or wood veneer strips. Compared to single-ply veneer, this leads to a significantly more uniform, usually higher force absorption and load-bearing capacity of the lightweight construction element, which is also made possible by the choice of different ply woods, e.g. Plywood or laminated wood, or wood veneer strips, can also be adapted to particularly high demands on torsional and / or flexural strength.

In this case it is advantageous if the ply wood or veneer strip wood is made of different types of wood in its thickness direction or across it. This enables an even more extensive adaptation to specific requirements.

A preferred embodiment is characterized by a fourth layer which is substantially parallel to the first and to which the second layer is glued to the apices of its second folds or to another of its end faces extending transversely to the folds. In this way, a particularly flexurally and torsionally stiff lightweight construction element can be achieved which also has a closed surface on both sides. In cases where the second layer is glued to the apex of its first folds with the first layer and at the apex of its second folds to the fourth layer, it is advantageous if the fourth layer has webs protruding between adjacent second folds of the second layer, of which each is glued to the flanks of two adjacent second folds of the second layer. This significantly increases the compressive strength of the lightweight construction element; bending and torsional stiffness are also increased. The structure of the lightweight construction element with three layers is relatively simple and the element is light and yet stable.

An alternative to the aforementioned embodiment, particularly preferred embodiment comprises a fourth layer substantially parallel to the first, with which the third layer is glued to the apices of its first folds or at least the second layer to another of its end faces extending transversely to the folds. In this embodiment, too, a particularly flexurally and torsionally stiff lightweight construction element is created, which can be used flexibly due to its surface closed on both sides.

The invention is explained in more detail below with reference to exemplary embodiments shown in the accompanying drawings. In the drawings show:

1 and 2 each show a detail of an embodiment of a lightweight construction element according to the invention made of wood in a perspective view obliquely from above; and

3 to 8 each show a detail of a further embodiment of the lightweight construction element according to the invention in a side view.

Fig. 1 shows a first embodiment of a lightweight construction element 1 made of wood. The lightweight construction element 1 has a first layer 2 which is essentially flat; “Essentially” in this context means that the first layer 2 is flat over its entire surface or can have a slight curvature. Furthermore, the lightweight construction element 1 comprises a second layer 3 which is glued to the first layer 2, e.g. glued, is. The second layer 3 is gathered into alternating first and second folds 4, 5, i.e. multiple curved. The first and second folds 4, 5 are directed in opposite directions; In the illustration of FIG. 1, the first folds 4 are directed downwards and the second folds 5 are directed upwards. On a front end face 6 of the second layer 3 it can also be seen that the first and second folds 4, 5 differ from one another in their respective radii of curvature r ;, r2, the radius of curvature r +; of the first folds 4 is greater than the radius of curvature r> of the second folds 5. This results in an approximately meandering course of the second layer 3 transversely to the folds 4, 5, which is also shown on its front and rear end faces 6, 7.

The first folds 4 each have an apex 8 and on both sides of the apex 8 a flank, i. (In the view of FIG. 1) a left flank 9 to the left of the apex 8 and a right flank 10 to the right of the apex 8 of the first fold 4. The left flank 9 of a first fold 4 is in each case with the right flank 10 of an adjacent one on the left first fold 4 and the right flank 10 of the first fold 4 is glued to the left flank 9 of a first fold 4 adjacent to the right.

Similarly, the second folds 5 each have an apex 11 and on both sides of the apex 11 a flank, i. (in the view of FIG. 1) a left flank 12 to the left of the apex 11 and a right flank 13 to the right of the apex 11 of the second fold 5. In contrast to the first folds 4, the flanks 12, 13 of the second folds 5 are due to their smaller radius of curvature 'r2 spaced from the flanks 12, 13 of an adjacent second fold 5, ie the left flank 12 of a second fold 5 is spaced from the right flank 13 of a second fold 5 adjacent to the left and the right flank 13 of the second fold 5 is spaced from the left flank 12 of a second fold 5 adjacent to the right. Since the first and second folds 4, 5 up

follow one another, they merge into one another, i.e. that e.g. a right flank 10 of a first fold 4 merges into a left flank 12 (viewed from left to right) of the following second fold 5 of the second layer 3 without any recognizable delimitation.

The lightweight construction element 1 of FIG. 2 differs from that of FIG. 1 in that, in the example of FIG. 1, the second layer 5 is glued to the first layer 2 at apices 8 of its first folds 4. In contrast to this, in the example in FIG. 2, the second layer 3 is glued to the first layer 2 on one of its end faces 6, 7 (here: the rear end face 7) running transversely to the folds 4, 5.

In the optional embodiment of FIG. 3, one of the first folds 4 of the second layer 3 has an apex 8 that is widened compared to other first folds 4. this first fold 4 is e.g. as a result of an at least partially larger radius of curvature r; its apex 8 and / or due to a flat section 14 in the apex 8 as in this example, wider than other first folds 4. This results in a greater distance between the left and right flanks 9, 10 of this first fold 4 and at the same time a greater distance between the two next second folds 5 in the alternating sequence. The lightweight construction element 1 thus forms a channel 15 in which, for example Pipelines, electrical lines or the like. inserted or snapped between the second folds 5.

4 shows a further optional embodiment of the lightweight construction element 1 with a third layer 16. The third layer 16 is also gathered to form alternating first and second folds 17, 18 which are directed in opposite directions. The third layer 16 corresponds to an overturned second layer 3 in that the second folds 18 of the third layer 16 face the second layer 3 (here: pointing downwards). The second folds 18 of the third layer 16 mesh with the second folds 5 of the second layer 3, i.e. they are gear or rack-like in mutual engagement.

The - here upwardly directed - first folds 17 of the third layer 16 each have an apex 19 and on both sides of the apex 19 a flank 20, 21, which (as in the second layer 3) with a flank 20, 21 of an adjacent first fold 17 of the third layer 16 is glued. The second folds 18 of the third layer 16 each have an apex 22 and a flank 23, 24 on both sides of the apex 22. The flanks 23, 24 of the second folds 18 of the third layer 16 each have a flank 12, 13 of an adjacent second Fold 5 of the second layer 3 glued together so that the second and third layers 3, 16 are glued to one another at the flanks 12, 13, 23, 24 of their intermeshing second folds 5, 18. The second and third layers 3, 16 are spaced from each other at the apices 8, 11, 19, 22 of their first and second folds 4, 5, 17, 18, i.e. the vertices 8 of the first folds 4 of the second layer 3 are in particular from the vertices 22 of the second folds 18 of the third layer 16 and the vertices 11 of the second folds 5 of the second layer 3 are in particular from the vertices 19 of the first folds 17 of the third layer 16 spaced.

The lightweight construction element 1 in the example of FIG. 4 also has a first layer 2, which is made of plywood (here: a two-layer plywood). Alternatively, instead of a plywood in which the wood fibers of adjacent layers are each at right angles to one another, e.g. be a plywood, in particular laminated veneer lumber, in which adjacent layers do not have perpendicular, but mostly parallel wood fiber directions; instead of ply wood, the first layer 2 could also be made of wood strips or the like. be. Alternatively or in addition, the second and / or third layer 3, 16 made of ply wood, wood veneer or the like. as will be explained in more detail below with reference to the example of FIG.

It is understood that in the exemplary embodiments without a third layer 16, the first and / or second layer 2, 3 each made of ply wood, wood veneer or the like. can be. Furthermore, in some embodiments, the first, the second and / or the third layer 2, 3, 16 is made of veneer.

FIG. 5 shows an embodiment alternative to FIG. 4, in which the third layer 16

again corresponds to a fallen second layer 3. In this case, too, the third layer 16 is gathered into alternating, oppositely directed first and second folds 17, 18, the second folds 18 of the third layer 16 meshing with the second folds 5 of the second layer 3. Again, the first folds 17 of the third layer 16 each have an apex 19 to which - in contrast to the exemplary embodiment in FIG. 4 - the apex 11 of a second fold 5 of the second layer 3 is glued inside the first fold 17 of the third layer 16 . On both sides of the apex 19, the first fold 17 of the third layer 16 each has a flank 20, 21 which is glued to a flank 20, 21 of an adjacent first fold 17 of the third layer 16, i.e. again a left flank 20 with a right flank 21 of the first fold 17 adjacent to the left, etc. Likewise, the second folds 18 of the third layer 16 each have an apex 22 glued to the apex 8 inside a first fold 4 of the second layer 3 and on both sides of the Apex 22 each have a flank 23, 24. The second and third layer 3, 16 are - in contrast to the example of FIG. 4 - from one another on the flanks 9, 10, 12, 13, 20, 21, 23, 24 of their first and second folds 4, 5, 17, 18 spaced apart.

In the example of Figure 5, the lightweight construction element 1 further comprises an optional fourth layer 25, e.g. Veneer, ply wood, wood veneer strips or the like. The fourth layer 25 is essentially parallel to the first layer 2 and is therefore just as flat or slightly curved as this. With the fourth layer 25, the third layer 16 is glued to the apices 19 of its first folds 17. The fourth layer 25 is thus glued to the third layer 16 on the side of the second layer 3 opposite the first layer 2; first, second, third and fourth layers 2, 3, 16, 25 thus form a sandwich lightweight construction element 1.

It will be understood that, as an alternative to this, the fourth layer 25, if the second layer 3 would be glued to the first layer 2 at one of its end faces 6, 7 extending transversely to the folds 4, 5, e.g. on the rear end face 7 (FIG. 2), with the second layer 3 on another of its end faces 6, 7 running transversely to the folds 4, 5 (here: the front face 6) can be glued (not shown). In addition, the third layer 16 can also be glued to the fourth layer 25 at their respective end faces in this case.

In the example of FIG. 6, the lightweight construction element 1 again comprises a fourth layer 25, but not a third layer 16. The second layer 3 is at the vertices 8 of its first folds 4 with the first layer and at the vertices 11 of its second Fold 5 glued to the fourth layer 25. In the exemplary embodiment in FIG. 6, the fourth layer 25 also has optional webs 26 which protrude between adjacent second folds 5 of the second layer 3. Each of the webs 26 is glued to the flanks 12, 13 of two adjacent second folds 5 of the second layer 3.

If the fourth layer 25 has no webs 26, the second layer 3 can alternatively be glued to the first and fourth layers 2, 25 at both of its end faces 6, 7, i.e. on the front end 6 with the fourth layer 25 and on the rear end 7 (FIG. 2) with the first layer 2 or vice versa.

FIG. 7 shows a variant of the exemplary embodiment of the lightweight construction element 1 shown in FIG. 3 with an additional third layer 16. In this example, one of the first folds 17 has the third layer 16, as does a first fold 4 that is approximately opposite this of the second layer 3, an apex 19 that is widened compared to other first folds 17 of the third layer 16. Again, this results in a channel 15, which in this case is enclosed between the second and third layer 3, 16.

In the embodiment shown in FIG. 8, the first layer 2 is made of a three-layer ply wood, the second layer 3 is made of veneer and the third layer 16, which - comparable to the embodiment of FIG. 4 - of the vertices 8, 11 of the second layer 3 at the apices 19, 22 of their first and second folds 17, 18 is spaced, made of two-layer ply wood (here: plywood). Each layer 27, 28 of the plywood of the third layer 16 is divided transversely to the end faces 6, 7 into segments 29, 30, 31, 32, which are made of different types of wood and optionally follow one another periodically. In this way, the laminated wood of the third layer 16 is partly made of different types of wood in its thickness direction 33 and in any case transversely thereto. As a result, the strength and flexibility of the third layer 16 can be adapted to the desired

nits can be adjusted.

It goes without saying that instead of or in addition to the third layer 16, the first, the second and / or the fourth layer 2, 3, 25 or the like made of ply wood or veneer strip wood. with different types of wood in its thickness direction 33 and / or transversely thereto. Furthermore, at least one of the first, second, third or fourth layers 2, 3, 16, 25 can extend in its longitudinal and / or transverse direction - e.g. periodic - have varying thickness. In general, the variants and features of the lightweight construction element 1 described for various examples or embodiments can be combined with one another in manifold ways, as can be immediately recognized by specialists. The lightweight construction element 1 can also optionally be integrated into another wooden construction element, e.g. another lightweight component, integrated.

The invention is not limited to the illustrated embodiments, but includes all variants, modifications and combinations thereof that fall within the scope of the attached claims.

Claims (9)

Claims 1. A lightweight construction element made of wood comprising a substantially flat first layer (2) and a second layer (3) bonded to the first, characterized in that at least one of the first and second layers (2, 3) is made of veneer and the second layer (3) is gathered to form alternating, oppositely directed first and second folds (4, 5), the first folds (4) each having an apex (8) and one with a flank (8, 9) on both sides of the apex (8) an adjacent first fold (4) have glued flanks (8, 9) and the second folds (5) each have an apex (11) and on both sides of the apex (11) one of a flank (12, 13) of an adjacent second fold (5 ) have spaced flanks (12, 13), and wherein the second layer (3) at the apices (8) of its first folds (4) or on one of its end faces (6, 7) running transversely to the folds (4, 5) is glued to the first layer (2). 2. Lightweight construction element according to claim 1, characterized in that one of the first folds (4) has an apex (8) that is widened relative to the other first folds (4). 3. Lightweight construction element according to claim 1 or 2, characterized by a third layer (16) which is gathered to form alternating, oppositely directed first and second folds (17, 18), which second folds (18) with the second folds (5) the second layer (3), the first folds (17) of the third layer (16) each having an apex (19) and on both sides of the apex (19) one with a flank (20, 21) of an adjacent first fold (17) the third layer (16) have glued flanks (20, 21) and the second folds (18) of the third layer (16) each have an apex (22) and one with a flank (12, 13) on both sides of the apex (22) adjacent second fold (5) of the second layer (3) have glued flanks (23, 24), and wherein the second and third layer (3, 16) from each other at the apices (8, 11, 19, 22) of their first and second Folds (4, 5, 17, 18) are spaced apart. 4. Lightweight construction element according to claim 1 or 2, characterized by a third layer (16) which is gathered into alternating, oppositely directed first and second folds (17, 18), which second folds (18) with the second folds (5) the second layer (3), the first folds (17) of the third layer (16) each having an apex (19) with which the apex (11) of a second fold (5) of the second layer (3) inside the first fold (17) of the third layer (16) is glued, and on both sides of the apex (11) a flank (20, 21) glued to a flank (20, 21) of an adjacent first fold (17) of the third layer (16) and the second folds (18) of the third layer (16) each have an apex (22) glued to the apex (8) inside a first fold (4) of the second layer (3) and a flank on both sides of the apex (22) (23, 24), and wherein the second and third layer (3, 16) from each other on the flanks (9, 10, 12, 13, 20, 21, 23 , 24) their first and second folds (4, 5, 17, 18) are spaced apart. 5. Lightweight construction element according to one of claims 1 to 4, characterized in that at least one of the first, second and third layers (2, 3, 16) is made of laminated wood or veneer strip wood. 6. Lightweight construction element according to claim 5, characterized in that the ply wood or veneer strip wood in its thickness direction (33) or transversely thereto is made of different types of wood. 7. Lightweight construction element according to claim 1 or 2, characterized by a fourth layer (25) which is substantially parallel to the first and with which the second layer (3) at the apices (11) of its second folds (5) or at another of its transverse to the folds (4, 5) extending end faces (6, 7) is glued. 8. Lightweight construction element according to claim 7, wherein the second layer (3) at the vertices (8) of its first folds (4) with the first layer (2) and at the vertices (11) of its second folds (5) with the fourth layer (25) is glued, characterized in that the fourth layer (25) has webs (26) projecting between adjacent second folds (5) of the second layer (3) each of which is glued to the flanks (12, 13) of two adjacent second folds (5) of the second layer (3). 9. Lightweight construction element according to one of claims 3 to 6, characterized by a fourth layer (25) which is substantially parallel to the first and with which the third layer (16) at apices (19) of its first folds (17) or at least the second layer ( 3) is glued to another of its end faces (6, 7) running transversely to the folds (4, 5). For this purpose 2 sheets of drawings