EP3211151A1 - Wooden beams in the form of a lamellae binder - Google Patents

Abstract

An improved timber beam in the manner of a lamellar binder is characterized, inter alia, by the following features: - With a lamellar composite with at least three interconnected lamellae (L; L1, L2) which consist of at least 70 percent by volume and / or at least 70 percent by weight of wood, wood components and / or wood materials or at least 70 percent by volume and / or at least 70 percent by weight Wood, wood components and / or wood materials include, or the lamellae (L; L1, L2) consist of a first lamella type (L1) and a second lamella type (L2), - The lamellar composite consists and comprises a lamellar structure, a) with two laterally offset from each other at a distance lamellae (L1) of the first lamella type and an interposed and non-positively connected to the lamellae (L1) of the first lamella type further lamella (L2) of the second lamella type or b) having two laterally staggered spaced lamellae (L2) of the second lamella type and an interposed and frictionally connected to the lamellae (L2) of the second lamella type further lamella (L1) of the first lamella type, - The modulus of elasticity of the lamella (L2) of the second lamella type is equal to the modulus of elasticity of the lamella (L1) of the first lamella type or has a value which is up to 50% above the value of the modulus of elasticity the lamella (L1) of the first lamella type is, and the strength of the second fin type fin (L2) is greater by a factor (F) than the strength of the first fin type fin (L1), the factor (F) being greater than or equal to 1.4 and / or less than Is 4.0.

Description

The invention relates to a timber carrier according to the preamble of claim 1.

In construction, a variety of carriers and types of support structures are known.

In the construction of halls it is known, e.g. for roof structures (including flat roofs) to use metal support, in particular so-called double-T-beams, which are often referred to as I-beam. In addition to a generally vertically extending web, they have an upper and a lower flange, which has belt sections aligned transversely to the vertically extending web level. The upper belt is subjected to pressure and the lower belt to train.

Such carriers must be designed to accommodate the corresponding loads in appropriate massiveness. This not only leads to a cost increase but also to an increase in weight, whereby the forces to be absorbed via the supporting structure in turn are relatively reduced.

In timber construction and wood construction technology, lattice girders have always been used. A lattice girder for a framework likewise likewise comprises, as is known, a top chord and a lower chord disposed at a greater distance therefrom, which are generally arranged running parallel to one another. Between the upper and the lower belt are then offset in the longitudinal direction of the carrier offset from each other and arranged diagonally aligned struts, which act and serve depending on the force stress as compression struts or tension struts. It can be distinguished between an overstretched and under-stressed support structure.

Furthermore, constructions have also become known in timber construction, for example using glued laminated timber (BSH). A method for producing a longitudinal connection of timber components and a corresponding wooden component is, for example, from EP 2 227 605 B1 known.

An improved in terms of its carrying capacity wood carrier is also from the WO 2015/120865 A1 known. The wooden support known therefrom comprises a support web extending in the longitudinal direction of the wood support, in which recesses are incorporated. These recesses extend only over a partial height of the support web. The wood carrier itself can be made of veneer wood panels (FSH), which comparatively are inexpensive to produce. The provided in the prior art upper belt covering the recesses introduced in the carrier may for example consist of glulam (BSH) or veneer lumber (FSH) or include these materials. For this purpose, conifers as well as hardwoods can be used.

Object of the present invention is based on the generic state of the art to provide an improved wooden beams, which can accommodate the highest possible loads and also has advantages over previous solutions in so far as that the wood support according to the invention can not suddenly fail by at Overload of the carrier suddenly breaks without notice.

The object is achieved according to the features specified in claim 1. Advantageous embodiments of the invention are specified in the subclaims.

The wooden support according to the invention consists of a lamellar binder which on the one hand has a high degree of robustness and on the other hand is characterized by its ductile carrying behavior. In the case of wooden girders or even lamellar binders in general, which should be suitable for high payloads and bearing reserves, there has always been the problem that, in the case of excessively high loads or overloads, a breakage of the timber girder does not occur. If the timber carrier could no longer take up the load, it is unpredictable and spontaneously the wearer suddenly broke, ie in its entire cross-section, so that its supporting function so suddenly eliminated.

In contrast, the wood support according to the invention in the form of a lamella binder has the significant advantage that a sudden failure of the lamellar binder is avoided. In other words, a fracture of the lamellar binder due to excessive loads or overloads would initially announce only by a partial failure of individual lamellae. This breach announcement is audible and clearly visible. However, the lamellar binder is not yet broken with respect to remaining lamellae or layers of wood.

In other words, a solution is proposed in the invention in which a partial failure of individual wood slats announces long before the breaking load of the timber support in total, i. the breaking load of the composite cross-section is reached. Therefore, these wood troughs according to the invention formed by type of lamellar binder can be referred to as robust structures.

This carrying or breaking behavior is realized in the invention in that the wooden support according to the invention has at least three lamellae, layers or layers, the two outer layers, layers or lamellae, for example, consist of glued laminated timber (BSH) and in between a middle lamella, layer or layer is glued, which consists for example of laminated veneer lumber (LVL). Alternatively, it is possible that the at least three lamellae, layers or layers comprising wood beams two outer slats, layers or Layers, for example, made of laminated veneer lumber (LVL) are formed, and that in between a middle layer is glued, which consists for example of glued laminated timber (BSH).

It is important within the scope of the invention that the modulus of elasticity of the lamellae preferably made of laminated veneer lumber (LVL or FSH) has a value which is equal to or greater than the value of the modulus of elasticity of the lamella, preferably consisting of glulam (BSH), Layer or layer. It is preferably sufficient if the modulus of this BSH slat, for example, max. 50% above the modulus of elasticity of the glued laminated timber lamella.

Alternatively or preferably cumulatively, it is further provided within the scope of the invention that the lamellae, which are preferably made of glued laminated timber or of laminated veneer lumber, have different strengths. The strength is known to be defined by the voltage to be absorbed (whose unit is measured N / mm ² ).

In order to ultimately increase within the scope of the invention preferably to be absorbed by the glulam slats loads and stresses and / or announce possible breakage hazards early, without the entire timber suddenly and unexpectedly and unpredictably breaks, it is provided that the strength of preferably veneer lumber ( LVL) existing lamellae on the strength of preferably made of glulam (BSH) lamellae. Preferably, the strength of the respective example of veneer lumber (LVL) existing lamella should be at least a factor of 1.4, and preferably 1.5 ... 2.0. It is in the Usually sufficient, if the strength preferably of the laminated veneer lamella is not more than four times as large as the strength of the glued laminated timber used to a slat connector preferably used.

The sudden total breakage of previously used wood beams also in the form of lamellar binders has been caused because lamellae were glued together with the same or similar modulus of elasticity and / or the strength of the individual lamellae was the same, so that in these cases under overload conditions could come a spontaneous brittle fracture of the timber carrier, ie a total failure of the binder, usually, for example, when a wooden beam was made of pure glued laminated timber.

The inventive solution with the explained different modulus of elasticity and / or the different strengths of the slats ensures that it can only come to a failure of individual slats in a multi-lamella wood support, in particular to a failure of the individual slats in the form of glued laminated timber , this failure taking place beginning from the Zugzonenrand upwards. Even if such a slat, for example consisting of laminated timber, breaks, the remaining slats and in particular the remaining one or more veneer plywood slats can still take up the necessary carrying forces.

• hohe Querdruckfestigkeit (an Krafteinleitungspunkten z. B. am Auflager)
• hohe Querzugfestigkeit (an Anschlüssen, große Durchbrüche und Ausklinkungen realisierbar, Querzugverstärkung gekrümmter Bauteile)
• hohe Scherfestigkeit (an Zwischenauflagern von Durchlaufträgern, in Anschlussbereichen, große Durchbrüche und Ausklinkungen realisierbar)
• hohe Dimensionsstabilität über die Querschnittshöhe (minimales Quell- und Schwindverhalten)
• leistungsfähige Anschlüsse realisierbar (Anschluss am LVL, kein Querzugproblem)
• verbesserte Stabilität der Bauteile gegen Knicken und Kippen bei Verwendung von mindestens zwei seitlich angeordneten LVL Lamellen
• verbesserte Torsionsfestigkeit bei Verwendung von mindestens zwei seitlich angeordneten LVL Lamellen

The wood support according to the invention in the form of a lamellar binder also has the other significant advantages or properties, namely:

• high transverse compressive strength (at force application points, eg on the support)
• high transverse tensile strength (can be realized at connections, large openings and notches, transverse tensile reinforcement of curved components)
• high shear strength (at intermediate supports of continuous beams, in connection areas, large breakthroughs and notches possible)
• high dimensional stability over the cross-section height (minimal swelling and shrinkage behavior)
• powerful connections can be realized (connection to the LVL, no cross-train problem)
• improved stability of the components against kinking and tilting when using at least two laterally arranged LVL slats
• Improved torsional strength when using at least two laterally arranged LVL slats

It is further noted that it is sufficient in the context of the invention if the lamella composite according to the invention consists at least predominantly of wood, wood components and / or wood-based materials or at least predominantly comprises wood, wood components and / or wood-based materials. In other words, the preferred advantages according to the invention can be realized if the described laminated composite consists of at least 70%, preferably at least 80%, 90%, or at least 95% of wood, wood components and / or wood-based materials or at least 70%, 80%. , 90% or at least 95% wood, wood components and / or wood-based materials. The remaining portion may be supplemented by other materials and materials having the desired characteristics as explained above. The percentages given above mean percentages by volume and / or percentages by weight. In this case, these percentages relate to the respective total lamellar connectors and preferably to the individual lamella types.

Figur 1:

eine schematische Seitenansicht eines erfindungsgemäßen Holzträgers;

Figur 2:

eine schematische Draufsicht auf den in Figur 1 gezeigten erfindungsgemäßen Holzträger;

Figur 3a:

einen Querschnitt quer zur Längserstreckung des in Figur 1 und 2 gezeigten erfindungsgemäßen Holzträger, und zwar gemäß eines ersten Ausführungsbeispiels;

Figur 3b:

eine Darstellung entsprechend zu Figur 3a in größerem Detail;

Figur 3c:

eine weiter Querschnittsdarstellung ähnlich zu Figur 3b, jedoch unter Darstellung geringfügiger weiterer Abwandlungen;

Figur 4:

eine Querschnittsdarstellung abweichend zu den Figuren 3a bis 3c bezüglich eines abgewandelten erfindungsgemäßen Ausführungsbeispiels;

Figur 5:

ein nochmals im Querschnitt gezeigtes weiteres Ausführungsbeispiel mit fünf Lamellen;

Figur 6:

ein nochmals abgewandeltes Ausführungsbeispiel der Erfindung im Querschnitt, ebenfalls mit fünf Lamellen, jedoch in anderer Lamellenfolge; und

Figur 7:

ein weiteres Ausführungsbeispiel in schematischer Seitenansicht vergleichbar zu Figur 1, jedoch mit mehreren den Holzträger quer zur Vertikalrichtung durchsetzenden Öffnungen.

The invention will be further explained with reference to drawings. This shows in detail

FIG. 1:

a schematic side view of a wooden support according to the invention;

FIG. 2:

a schematic plan view of the in FIG. 1 shown wood support according to the invention;

FIG. 3a:

a cross section transverse to the longitudinal extent of in FIGS. 1 and 2 shown wood carrier according to the invention, according to a first embodiment;

FIG. 3b:

a representation corresponding to FIG. 3a in greater detail;

FIG. 3c:

a broad cross-sectional view similar to FIG. 3b , but showing minor further modifications;

FIG. 4:

a cross-sectional representation deviating from the FIGS. 3a to 3c with respect to a modified embodiment according to the invention;

FIG. 5:

a further embodiment shown in cross section with five fins;

FIG. 6:

a further modified embodiment of the invention in cross section, also with five lamellae, but in a different slat sequence; and

FIG. 7:

another embodiment in a schematic side view comparable to FIG. 1 , but with several openings passing through the wooden beams transversely to the vertical direction.

In FIG. 1 is shown in a schematic side view and in Figure 2 in a schematic plan view of a wooden support 1, which is formed in the invention in the manner of a lamellar binder 3.

In FIG. 3a is a cross section along the line III - III through FIG. 1 played.

The wooden beam in the manner of a lamellar binder thus comprises in the embodiment shown three standing slats L, namely a first central or central slat L1, sandwiched between two outer Slats L2 is included. All three blades are connected to each other non-positively, in particular glued.

The lamellar binder according to FIGS. 1, 2 or 3a has, for example, a length X, a height H and a width or thickness B, as shown Figures 1 and 2 can be seen.

As a result, two longitudinal sides 5, an upper and lower side 7 and two opposite end faces 9 are formed.

The mentioned in the embodiment shown 3 slats comprehensive lamellae has according to the present first embodiment, two outer slats L, L2, which are formed in the illustrated embodiment of veneer lumber, which is abbreviated abbreviated FSH or LVL (LVL = Laminated Veneer Lumber).

A veneer lumber wood is therefore a wood material, as it is often used in timber construction. In this case, such veneer plywood usually consists of about 3 mm thick peeled veneers. This softwood is often used. Also in use are also the most diverse hardwoods. This veneer plywood can then be used for surface structures as well as for solid wood beams in the form of beams, etc.

In veneer lumbers, these are preferably glued together in a parallel fiber shape so that material properties such as strength values are strong are directional. You can - as will be discussed below - but also in layers, for example, glued to each other by 90 ° or in another angular position. This results in different or constant strength values in different directions.

In the FIG. 3a shown middle slat L, L1 is formed in contrast to the outer slats L2 not from veneer lumber but from glued laminated timber, which is also abbreviated hereafter BSH. Glued laminated timber is understood as meaning glued woods, which as a rule comprise at least four board layers and are preferably glued together in the same fiber direction. These glulam beams are also often used in engineering timber construction to absorb high static forces here.

In FIG. 3b is indicated that the middle slat L1 can be composed of several board layers or board layers 11. In the variant according to FIG. 3b, for example, 8 board timbers are glued together, each with their large side surface.

Assuming that such wooden beams are installed in the form of lamellar binder aligned in the vertical direction V, it follows that the veneer layers FS are arranged under formation of the veneer lumber FSH in the vertical direction V and glued together with their large side surfaces FS1, whereas the board layers or Bretthölzer 11 aligned with their greater longitudinal extent in the horizontal direction H and then in the vertical direction one above the other are arranged so that they are glued together in the vertical direction with their large side surfaces. The outer slat L2 with the laminated veneer lumber is thus glued with its large and inward side surface FSH1 at the end faces BSH1 of the glued laminated timber with these.

The peculiarity of this invention timber carrier or lamellar binder is now characterized by the fact that the lamellae L, L1, L2 formed from different woods and / or produced using different woods at least have an approximately equal or not too different from each other modulus E. In the exemplary embodiment shown, the laminated wood-lamella L1 is optimized with respect to its load-bearing behavior by the veneer lumber slats L2.

For this purpose, it is provided that the modulus of elasticity of existing veneer plywood or veneer plywood lamella L, L2 has an E-module, which corresponds to the modulus of elasticity of this embodiment, the average glulam lamella L, L1 or greater. In particular, however, the modulus of elasticity of laminated glued laminated lath L1 is only 50% higher than the modulus of elasticity of laminated veneer lamellae L2. Preferably, the modulus of elasticity of the laminated timber slat L1 or the corresponding slat L1 is generally only about 45%, preferably only at most 40%, 35%, 30%, 25%, 20%, 15%, 10% and preferably only by 5% above the modulus of elasticity of the further lamella L2, ie preferably the laminated veneer lamella L2.

Alternatively and additionally, it is likewise provided that the strength of the successive lamellae L2-L1-L2 is different.

The strength is defined as the voltage to be absorbed in N / mm ² .

It is now provided that the strength of the laminated veneer lamella L2 is greater than the strength of the laminated timber lamella L1.

In this case, the factor F by which the strength of the laminated veneer lamella L2 is greater than the strength of the laminated lamella L1 should preferably be at least 1.4, preferably at least 1.5, 1.6, 1.7, 1.8, 1.9 or at least 2.0. In the same way, however, this value can also be significantly higher, such that the aforementioned factor F is, for example, at least 2.1, 2.2, 2.3... 3.8, 3.9 and preferably at least 4.0.

Conversely, it is generally sufficient if the factor by which the strength of the lamella L2 consisting of laminated veneer lumber LVL is not greater than 4, preferably less than 3.9, 3.8, 3, compared with the lamination L1 consisting of glulam BSH . 7, 3.6, 3.5, 3.4, 3.3, 3.2, 3.1, 3.0 .

This arrangement ultimately results in a lamellar binder for high payloads and traverses, which has a ductile load bearing behavior. Ductile load-bearing behavior means nothing else than that, in contrast to previous solutions, there is no sudden failure of the lamellar binder. In contrast to the state of Technique in which too high load moments and loads can then lead to a very sudden total failure of the binder (total breakage of the binder), the lamellar binder according to the invention shows a behavior in which announces a possible breakage by a partial failure of a lamination L1 formed from glulam BSH. This partial failure is easily audible by a loud bang and visually also clearly visible. Nevertheless, the lamellar binder still carries, so that appropriate security measures can be initiated quickly.

This support or fracture behavior according to the invention arises because laminations are glued together with the same or with a similar modulus of elasticity. This modulus of elasticity ultimately means that the individual lamellae have a similar expansion behavior and oppose a more or less equal resistance to elastic deformation. In this case, the vote is such that the modulus of the slats L2, which are made of laminated veneer lumber LVL, is equal to or greater than the modulus of elasticity of laminated glulam BSH comprehensive lamellae, so that targeted - in a breakage trap - initially the glued laminated timber BSH comprehensive Slat breaks.

As explained, as an alternative or in addition, the strength of the laminations L2 comprising the laminated veneer lumber materials is preferably 1.4 to 4 times greater than the strength of the laminated laths or lamellae, there is no brittle fracture (total failure of the binder). as would normally be the case with a pure prior art glulam beam.

Instead, the individual single lamella consisting of glulam wood gradually fails (from the beginning of the Zugzone edge to the top).

Based on Figure 3c is shown only schematically that the glued laminated timber BSH comprehensive lamella L1 not only a row R1 with several superimposed glued board layers or board woods 11 must exist, but that, for example, two rows R1, R2 may be provided, preferably on their large side surfaces BSH1 consecutively each are glued together in pairs and also two such rows R1 and R2 are additionally glued to each other at their facing wood surfaces 15 together, resulting in an overall broader glued laminated timber L1.

Based on FIG. 4 an alternative embodiment is shown in which also three blades L are glued together.

In the variant according to FIG. 4 the middle lamella L2 consists of a lamella L made of laminated veneer lumber LVL.

At the large outwardly facing side surfaces of this laminated veneer lamella L2 is then in each case a lamella L1 consisting of glulam BSH non-positively connected, preferably fixed by means of sizing.

This results in a different slat sequence between the FIGS. 3a-3c on the one hand and Figures 4a and 4b on the other, namely Figure 3a - Figure 3c : L2 - L1 - L2 Figure 4a - Figure 4b: L1 - L2 - L1

The lamellae L1 thus preferably consist of a glued laminated timber structure, as described on the basis of the preceding exemplary embodiment according to FIGS FIGS. 3a to 3c was explained. Likewise, the lamella L2 persists in the variant FIG. 4 preferably from a construction, as has been explained with reference to the preceding drawings.

Therefore, according to the present invention, it is preferred to provide at least one upright lamellar connector which comprises at least three lamellae in one of the abovementioned sequences.

In this case, the structure of the slats is designed alternately transversely to their primary stress and stress direction, according to the explanations given above.

Furthermore, the structure is preferably symmetrical with respect to the vertical orientation V, ie generally symmetrical with respect to a central symmetry plane S. This central plane of symmetry runs through the middle of the central lamella L1 in the exemplary embodiment FIGS. 3a to 3c or by the middle of the lamella L2 according to the embodiment according to FIG. 4 , The respectively further outwardly adjoining further lamellae from the respective other wood material are insofar preferably also the same, ie constructed symmetrically, which is the use of the corresponding Woods, their composition and their width across the plane of symmetry.

This carrying or breaking behavior is achieved for the first time in a carrier made of wood components, because slats of wood and wood materials with the same or similar modulus E, but different strengths, are glued together.

The voltages present in the carrier are distributed over a constant cross-section with a constant modulus of elasticity across the carrier width under vertical load constant.

However, since the strengths of the wood-based material used are up to twice as high as those of the BSH slats used, these BSH slats fail much earlier than the FSH fractions combined with them.

The inability to absorb the BSH fins by these absorbable stresses are released and stored on the surrounding wood material components.

By the same or very similar modulus of elasticity of the wood material used, the total carrier deformation increases rapidly to a tension equilibrium rapidly, but it does not come to a brittle break due to the much higher strengths (total failure of the binder), as is the rule would be the case with a pure BSH carrier.

Instead, the individual louvers of the BSH gradually fail to be clearly visible and audible (starting from the edge of the train, towards the top).

This failure form was previously reserved in construction only for steel and reinforced concrete construction.

In the illustrated embodiments, therefore, comes as a lamellar material for a glued laminated timber BSH and other veneer lumber LVL (sometimes abbreviated FSH also known) used. However, other wood-based materials may also be added to the lamellar materials mentioned, or may replace them in part, for example wood-based materials with or without transverse layers (as required).

There is no limitation to certain binder forms in the context of the invention. Possible are so-called parallel binder, Fischbauchbinder or saddle roof truss etc., etc. All these lamellar binders are also feasible within the scope of the invention.

The tensile or pressure zones occurring depending on the constructive use can additionally be reinforced locally by high-strength lamellae. The result is a further increase in the payload and rigidity of the binder cross-sections.

The carrier components are preferably connected to each other non-positively (for example by gluing). Preferably, the slats are block-glued, as has been described with reference to the embodiments.

The following will be on FIG. 5 Referenced.

The embodiment according to FIG. 5 provides an extension to the embodiments Figure 3a - 3c represents.

Because of the lamellar binder according to FIGS. 3a to 3c with the three lamellas L2 - L1 - L2 in the form of the wooden sequence
LVL - BSH - LVL now undergoes an extension to the effect that on the two LVL layers according to Figure 3a - 3c each outside a further layer of wood is frictionally connected, that is preferably glued.

Here, according to the given sequence, a layer of glued-laminated glulam is externally glued on. This results in a 5-lamella structure, which is provided as preferred is also formed again symmetrically to the central symmetry or vertical plane S and V.

The corresponding example shows FIG. 6 for the reverse layer construction.

In the variant according to FIG. 6 is based on the examples according to FIG. 4 on the outside each still another layer provided, namely in this variant, in turn following the glulam slat L1 another outer slat L2 made of veneer lumber LVL. Again, the structure is again symmetrical to the mean vertical and / or symmetry plane V, S.

If necessary, further layer sequences could be realized.

From the described structure is thus apparent that due to the desired symmetry, especially an odd-numbered lamellar structure is preferred, ie a lamellar binder with 3, 5, 7 or more lamellae, in which preferably each a veneer lumber slat L2 and a glued laminated lath L1 alternate, ie in the direction in which the individual disks are non-positively connected preferably by gluing together.

The following is still on one FIG. 1 modified embodiment received in side view, which shows large transverse through the lamellar binder through openings 31 and other smaller openings 33 on the other hand.

These openings can be introduced into the binder and run, for example, between the two opposite generally larger-sized side surfaces 5. These openings can serve, for example, that in certain cases other support and / or ceiling structures and / or conduit systems including light pipe systems, etc. therethrough can be moved. Also in this case can be ensured by appropriate gluing of the individual slats as well as by specific orientations of the fibers, for example, the veneer lumber slats be that the voltages and carrying forces introduced into the lamellar binder, in particular in the area in front of and behind the openings, can be received via the material areas of the lamellar binder formed laterally by the openings.

The lamellae are aligned in the vertical direction V in all the embodiments shown, i. that usually the individual lamellae L, L1 and L2 are aligned in the vertical direction, ie extend in the height direction H with their greater extent, wherein the extension in height direction H for each lamella L, L1, L2 is usually greater than that in the width direction B extending extension.

Therefore, it is also spoken of a standing lamellar binder with at least three standing lamellae.

The thickness of the illustrated lamella L2, in particular in the form of laminated veneer lumber LVL lamella L2 has a thickness which corresponds to the thickness of the individual lamellae L1 preferably in the form of glulam wood layers BSH or less than 90%, preferably less than 80%, 60% , 40% or less than 20% of it deviates. The thickness or width B of the lamella L2 preferably made of laminated veneer lumber LVL preferably has a thickness which corresponds to the thickness of the lamella L1 preferably in the form of glulam BSH or at least not less than 10% of this value. In other words, if the laminated veneer lamella L2 has a thickness of 20 cm, the thickness of the laminated lath L1 may preferably be between 20 cm and a minimum value of 10% thereof, ie 2 cm.

It should also be noted that the illustrated embodiments have been explained so that preferably the veneer lumber lamination L2 has the same or up to a maximum of 50% greater modulus of elasticity than the glulam lamella L1, and that the strength of the laminated veneer lamella L2 is preferably at least 1.4 to preferably 4.0 times greater than the strength of the glulam lamella L1. It is again noted that the modulus of elasticity of the lamination type L2 in general and the laminated veneer lamella L2 in particular preferably at most 45%, particularly preferably at most 40%, 35%, 30%, 25%, 20%, 15%, 10% and preferably only a maximum of 5% greater than the modulus of elasticity of the other plate type L1, in particular in the form of the laminated glued laminated lath L1.

Generally, however, the invention can be realized so that the lamellae L, L1 and L2 are made of wood components, ie made of wood and wood-based materials, wherein the at least two different lamellae as described have the same or a correspondingly similar modulus of elasticity, but different Strengths, with the above limits. A limitation to the laminated veneer lamella and / or the glulam lamella is not so far, although the preferred embodiments have been explained with reference to these types of lamellae.

Therefore, it can generally be said that the lamella assembly comprising at least three lamellae always comprises two louvers L1 of a first louver type and at least one louver L2 of a second louver type or conversely two louvers L2 of the second louver type and at least one lamination L1 of the first louver type. In this case, the lamellae L1 and L2 in this case, too, those properties, as explained with reference to the above-mentioned embodiments with reference to the existing of glulam or veneer lumber wood slats.

As part of the various embodiments, especially glulam and veneer lumber have been addressed. Both conifers and hardwood or hardwood hybrid products can be used for the structural implementation within the scope of the invention. For example, beech glulam and beech hybrid glulam can be used. In other words, in the context of the invention, especially hardwood and hardwood hybrid glued laminated timber is suitable. Other hardwood products may also include or consist of laminated veneer lumber (LVL), including thermally modified wood, especially when used outdoors. Restrictions on certain types of wood do not exist in principle. In addition, if required, metallic parts and in particular supporting parts which are not made of wood, such as metal, steel, plastic, carbon, etc., could also be incorporated, wherein in the context of the invention the lamellar composite as a whole and / or the individual connected to the lamellar composite Slats predominantly or at least more than 70 weight and / or volume percent, preferably at least 80, 85, 90, 95, 96, 97, 98 or at least 99 weight percent and / or volume percent of wood, wood products and / or wood components exist (apart from the still to be used in addition non-positive connections, preferably in the form of glue, etc.).

In the case of the corresponding glulam lumbers and in particular the glued laminated lamellae, Glulam is also frequently spoken of, ie a term formed from the words "glued laminated timber", which stands for glued laminated timber.

Claims (13)

Wooden beam in the manner of a lamellar binder with the following features - With a lamellar composite with at least three interconnected lamellae (L; L1, L2) which consist of at least 70 percent by volume and / or at least 70 percent by weight of wood, wood components and / or wood materials or at least 70 percent by volume and / or at least 70 percent by weight Wood, wood components and / or wood materials include, or the lamellae (L; L1, L2) consist of a first lamella type (L1) and a second lamella type (L2), - The lamellar composite consists and comprises a lamellar structure, a) with two laterally offset from each other in spaced lamellae (L1) of the first type of lamella and an interposed and non-positively connected to the blades (L1) of the first lamella type further lamella (L2) of the second lamella type or b) having two laterally staggered spaced lamellae (L2) of the second lamella type and an interposed and frictionally connected to the lamellae (L2) of the second lamella type further lamella (L1) of the first lamella type, - The modulus of elasticity of the lamella (L2) of the second lamella type is equal to the modulus of elasticity of the lamella (L1) of the first lamella type or has a value which is up to 50% above the value of the modulus of elasticity the lamella (L1) of the first lamella type is, and the strength of the second fin type fin (L2) is greater by a factor (F) than the strength of the first fin type fin (L1), the factor (F) being greater than or equal to 1.4 and / or less than Is 4.0. Timber carrier according to claim 1, characterized in that at least one lamella (L1) of the first lamella type glued laminated timber (BSH) comprises or is formed therefrom, and in that the lamella (L2) of the second lamella type comprises laminated veneer lumber (LVL) or formed therefrom is. Wooden support according to claim 1 or 2, characterized in that the individual lamellae (L; L1, L2) with their relative to the longitudinal and / or end sides (5, 9) larger-sized side surfaces (17) non-positively connected, preferably glued together , Wooden support according to claim 1, 2 or 3, characterized in that lamellae (L; L1, L2) are formed symmetrically to a vertical and / or symmetry plane (V, S), which are parallel to the side surfaces (17) of the lamellae ( L; L1, L2) runs, at which the lamellae (L; L1, L2) are positively connected with each other, in particular glued together. Wooden support according to one of claims 1 to 4, characterized in that the wooden support comprises an odd number of lamellae (L; L1, L2) and preferably at least 5 or 7 lamellae (L; L1, L2). Wooden support according to one of claims 2 to 5, characterized in that the veneer lumber (LVL) comprehensive lamella (L2) comprises a plurality of veneer layers glued together, the fiber flow are glued in parallel position to each other or lying mainly in parallel position to each other. Timber carrier according to one of claims 2 to 5, characterized in that the veneer lumber (LVL) comprehensive lamella (L2) comprises a plurality of veneer layers glued together, the fiber profile preferably of adjacent layers alternately crosswise or predominantly crosswise. Timber carrier according to one of claims 2 to 7, characterized in that the thickness of the laminated veneer lumber (LVL) comprising lamella (L2) has a thickness which corresponds to the thickness of the individual glulam layers (11) of the glued laminated timber (BSH) lamella (L1) or less than 90%, in particular less than 80%, 60%, 40% or 20% thereof. Wood carrier according to one of claims 1 to 8, characterized in that in the timber carrier in the longitudinal direction (X) spaced openings (31,33) are introduced. Wooden support according to one of claims 1 to 9, characterized in that the width of the lamella (L1) of the first lamella type in the width direction (B) of the timber support (1) at least twice, preferably at least three times or at least four times and preferably less than seven times or six times as wide as the width (B) of the second-vane type sipe (L2). Wood support according to one of claims 1 to 10, characterized in that the lamella composite total or each of the at least three interconnected lamellae (L; L1, L2) at least 70%, preferably at least 80%, 90% or at least 95% Wood, wood components and / or wood-based materials consists or comprises at least 70%, 80%, 90% or at least 95% wood, wood components and / or wood-based materials. Wood carrier according to one of claims 1 to 11, characterized in that the factor (F) is greater than or equal to 1.5, 1.6, 1.7, 1.8, 1.9, 2.0 and / or less than 3 , 9, 3.8, 3.7, 3.6, 3.5, 3.4, 3.3, 3.2, 3.1, 3.0. Wooden support according to one of claims 1 to 12, characterized in that the modulus of elasticity of the lamella (L2) of the second lamella type has a value which up to a maximum of 45%, preferably up to a maximum of 40%, 35%, 30%, 25%, 20%, 15%, 10% and preferably up to a maximum of 5% above the value of the modulus of elasticity of the lamella (L1) of the first lamella Type is.

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