RU2575292C2 - Composite element and wooden wall unit - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: composite element includes an outer wooden structural element, and an inner wooden structural element located at the distance from it. A filler is arranged between two wooden structural elements. Both wooden structural elements, each on its side bordering the filler, have grooves. In particular, at least one, preferably each of wooden structural elements accordingly comprises two wooden layers. One of wooden layers of each wooden structural element in separate areas and on one side is equipped with grooves. The wooden layer that borders with the filler on its side facing the filler has grooves. Grooves are made in the form of parallel grooves. The wooden layer is formed from several oblong stocks located next to each other. All stocks of one wooden layer have parallel passing grooves. The wall unit and the structure are made of this composite element.

EFFECT: simplified manufacturing, reduced weight, improved insulation.

21 cl

Description

The invention relates to a composite element including an external wood structural element, as well as an internal wood structural element located at a distance from it, wherein a filler is located between the two wood structural elements.

In addition, the invention relates to a method for manufacturing a composite element.

Such slab composite elements are often used in the construction of houses from prefabricated parts, while one or more of these composite elements results in, for example, an external wall, roof or ceiling of such a building. A typical structure of such known wall, roof or ceiling elements includes two wood structural elements in the form of plates, which are connected to each other by means of framed wooden elements. Plates are connected to framed wooden elements, for example, using nails, brackets and other things. The intermediate space between the plates can be provided with thermal insulation, a place for installation work and others. Typically, the outer plate on the outside is again insulated and then plastered.

The disadvantage of these known elements is that the method of connecting the plates contributes to the formation of bridges of heat and cold. In addition, the disadvantage is that a relatively large number of work steps are necessary to connect the plates, fill the intermediate space and then supply the element with thermal insulation from the outside.

The objective of the invention is to eliminate these disadvantages from the prior art.

This problem is solved using the already mentioned composite element due to the fact that, in accordance with the invention, both wood structural elements each have recesses on their side adjacent to the filler, and these recesses in the sides bordering the filler are also filled with filler.

In the manufacture of the element according to the invention, the intermediate space between the wood structural elements is filled with a filler, for example, foamed. Due to this, the filler also falls into the recesses of the wood structural elements that face the (space filled with filler) intermediate space. When the aggregate solidifies, an extremely stable composite structure of aggregate wood is then obtained. Thus, a self-supporting composite element is formed, which is simple to manufacture and which can prevent the formation of heat and cold bridges, since there is no need for nails, screws and other things to connect two wood structural elements.

The aforementioned problem is also solved with the help of the aforementioned composite element, in which the intermediate space bounded by two wood structural elements is foamed (in the form of foam) by a filler, and this foam filler after foaming - in the solidified state of the filler - connects two wood structural elements to each other.

Such actions allow avoiding bonding of the aggregate with wood structural elements, which makes it possible to more easily and quickly manufacture composite elements.

The stability of the connection is significantly increased if both wood structural elements each have recesses on their side adjacent to the filler, and these recesses in the sides bordering the filler are also filled with filler.

In addition, the above problem is also solved using the method of manufacturing a composite element, while the method proposed by the invention includes the following steps:

*) positioning of two wood structural elements at a distance from each other,

*) foaming of the intermediate space formed by two wood structural elements with an aggregate in the form of foam,

*) solidification of the aggregate.

The foam aggregate hardens after injection due to appropriate actions, preferably as, for example, in the case of polyurethane foam, simply due to reaction with air, and thus connects the two wood structural elements to each other.

It is preferable if, before introducing the filler, recesses are made on the sides of the two wood structural elements facing the intermediate space, preferably in the form of grooves, which simultaneously foam when the intermediate space is foamed.

Preferably, the aggregate is an insulating material, due to which the composite element has very good heat-insulating properties, and there is no need for additional installation of insulation on the outside of the composite element, which accordingly significantly reduces the manufacture of the composite element and, in particular, also the required construction time of the building using such composite elements.

In principle, wood structural elements can consist of each of one single wood part.

But it is particularly preferable when at least one, preferably each of the wood structural elements, respectively, consists of at least two wood layers, and at least one of these wood layers of each wood structural element, at least in separate areas and at least at least on one side it is provided with recesses, while the wood layer that borders the aggregate has at least recesses on at least its side facing the aggregate.

Such wood structural elements are known from EP 0762951 B1, and this document describes the filling of all recesses (in the form of grooves), as well as those recesses that are in the element, foam filler, so as to provide good heat, cold and noise insulation properties of wood structural item. The wood structural element as such then forms the wall of the building.

In the present invention, on the contrary, such a wood structural element is used to form a composite element, the recesses are filled with filler only on the side facing the aggregate to create a composite structure, while the recesses inside the wood structural elements remain empty. Due to this, an extremely lightweight composite element can be manufactured.

In addition, during the construction of the building, in particular the house from the finished parts, the side surfaces of the composite elements are closed airtight after installation, which creates additional thermal insulation by means of an air cushion inside the element.

Significant weight savings are possible if the wood layer on both sides has recesses, and if these recesses are located on the entire surface of the side of the wood layer or, respectively, on the filler-facing sides of the wood structural elements, in particular if each of the wood layers is at least one, preferably has recesses on both sides.

A particularly simple manufacturing of the recesses is possible if they are made in the form of grooves substantially parallel to each other in wood structural elements, in particular in wood layers.

The grooves are usually straight and oblong, in the cross section they can be rectangular, trapezoidal, round, oval and other. Typically, the grooves are perpendicular to the surface, but they can also be inclined relative to the perpendicular to the surface at a certain angle, that is, be inclined in the wood layer.

Finally, the grooves may be curved or branched, which, however, as a rule, is not a preferred embodiment.

From the point of view of simple manufacture and in order to be able to realize the advantages described below, it is also preferable if, in the presence of grooves on both sides of the same wood layer, the grooves on both sides extend in the same direction with each other.

In order to be able to make the grooves in the wood layers as deep as possible, it is provided that the grooves on both sides are offset from each other in a direction transverse to the longitudinal direction of the grooves.

In order to increase the stability of the wood structural element, it is preferable that the grooves of the at least one wood layer extend laterally at an angle greater than zero relative to the grooves of the other wood layer.

In this regard, it is particularly preferable if the grooves of two adjacent wood layers extend laterally at an angle greater than zero relative to each other, and then the grooves of two adjacent wood layers that are separated by the wood layer extend parallel to each other.

Typically, the angle between the grooves of adjacent wood layers is from 60 ° to 120 °, preferably about 90 °.

For simple manufacturing, in particular for simple manufacturing by machine, it turned out to be preferable if the wood layer is formed of several parallel elongated blanks, and in the case of grooves, all blanks of the same wood layer have parallel grooves. In the presence of preferably straight grooves, they extend preferably in the direction of wood fiber.

When splitting (= making grooves) of workpieces (= wooden boards) on the upper and lower sides, boards usually warped around the longitudinal axis of the boards can be straightened out with significantly less labor on the production line and a significant reduction in the pressing pressure for gluing the boards.

The blanks of one wood layer with their lateral surfaces are snug against each other (there are recesses / grooves in the upper side and / or lower side), preferably they abut against each other.

Separate, slotted boards (blanks) are glued together with glue, for example PU (polyurethane) glue, then the wood layers are glued together again.

It is also preferable if the grooves extend in the longitudinal direction of the workpieces, while the workpieces of adjacent wood layers extend transversely, at an angle greater than zero relative to each other, and the angle between the workpieces of adjacent wood layers is from 60 ° to 120 °, preferably about 90 °.

If the boards are glued together at an angle equal to 45 ° to obtain an infinite element, and accordingly, the blanks of two adjacent wood layers are located one above the other 90 ° relative to each other (for example, in 2 or 4 layers respectively) and glued in this way, then the wood structural The element has maximum mechanical strength and stability. The wood structural element is made in the form of an endless element, i.e. the wood structural element has a certain width and thickness, and with respect to its longitudinal extent (production direction) is made “endless” and cut into the desired length of the wood structural element.

With the practical preferred width of the wood structural element, this requires a maximum length of the blank board of approximately 500 cm. If only shorter boards are available (at least 310 cm with the preferred width), the exact same element production on the production line is possible, but the angle the boards relative to each other should then lie between 30 ° and 60 °. In this case, the angle between adjacent wood layers also changes (60 ° -120 °), which reduces the mechanical strength of the wood structural element. But in this way, targeted control of the strength of the wood structure is also possible.

In order not to weaken the structure of the tree, it is preferable if the filler provides channels, voids and the like for installation work and so on. It is also the preferred option in terms of ease of manufacture.

In addition, the invention relates to a structure that is constructed using such composite elements.

The invention further relates to a wood wall block, a method for manufacturing a wood wall block, the use of such a wood wall block, and structures that are at least partially made from such wood wall blocks.

In the construction of buildings, such as, for example, single-family houses, famous bricks, wall blocks (Ytong) and so on are very often used. After the construction of the building envelope or the walls of the building, the walls are insulated from the outside, then the base for the plaster is applied to the insulation, and after the wall they are plastered.

The result of these separate necessary steps is the correspondingly long duration of the construction of the building. In addition, in order to achieve good insulation, relatively clean and accurate work is required by the contractor.

The objective of the invention is to provide a wall block, which is stable and lightweight and with which the duration of the construction of the building can be reduced. In addition, the objective of the invention is to create a wall block that will allow the construction of well-insulated walls.

These problems are solved due to the fact that the wall block is formed from the composite element proposed by the invention or from a part thereof.

Thus, a wood wall block is obtained in the form of a composite element, which is simple to manufacture and in which the occurrence of heat and cold bridges can be prevented, since there is no need for nails, screws and other things to connect two wood structural elements.

In one embodiment of a wood wall block, in which the intermediate space bounded by two wood structural elements is foamed (in the form of foam) by a filler, and this foam filler, after foaming - in the hardened state of the filler - connects two wood structural elements to each other, the filler is prevented from sticking together. with wood structural elements, which makes it possible to more easily and quickly manufacture composite elements.

In addition, the above problems are also solved using the method of manufacturing a wood wall block, and the invention proposed method includes the following steps:

a) positioning two wood structural elements at a distance from each other,

b) foaming of the intermediate space formed by two wood structural elements with an aggregate in the form of foam,

c) solidification of the aggregate,

d) cutting one or more wood wall blocks from a composite element obtained by steps a) to c).

In the present invention, the recesses are filled with filler only on the side facing the filler to create a connection, while the recesses inside the wood structural elements remain empty. Due to this, an extremely lightweight composite element or a correspondingly very light wood block wall can be manufactured.

For the simple manufacture of a composite element from which one or several wood-based wall blocks are then obtained, in particular for the simple manufacture of such a composite element by machine, it turned out to be preferable if one wood layer is formed from several parallel elongated preforms, and in the case of the presence of grooves, all the blanks of the same wood layer have parallel grooves. In the presence of preferably straight grooves, they extend preferably in the direction of wood fiber.

With the practical preferred width of the wood structural element, this requires a maximum length of the blank board of approximately 500 cm. If only shorter boards are available (at least 310 cm with the preferred width), the exact same element production on the production line is possible, but the angle the boards relative to each other should then lie between 30 ° and 60 °. In this case, the angle between adjacent wood layers also changes (60 ° -120 °), which reduces the mechanical strength of the wood structural element. But in this way, targeted control of the strength of the wood structure is also possible. From the composite element made in this way, wood wall blocks of the desired size are then cut out, or accordingly, wood wall blocks are also cut from parts of such composite elements, which, for example, are formed as waste when cutting windows or doors from composite elements.

Below the invention is explained in more detail using the drawings, which show:

figure 1 - plate (composite) element of the invention, in perspective view,

figure 2 - untreated elongated wood element in perspective view,

figure 3 - wood element shown in figure 2, provided with grooves in the direction of the longitudinal extent of the wood element,

figa - a fragment of the wood element shown in figure 3, in an enlarged image,

figure 4 - wood element, shown in figure 3, with a view of the end side of the element,

figure 5 is a perspective view of the workpiece from the wood element shown in figure 3, for the manufacture of wood layers for the slab element, in perspective view,

figa is a fragment of the workpiece shown in figure 5, in an enlarged image,

6 is a cutting of a wood element,

7 is a wood layer composed of a number of blanks in perspective view,

figa - a fragment of the wood layer shown in Fig.7, in an enlarged image,

Fig.8 is a wood layer, shown in Fig.7, in a schematic top view during manufacture,

Fig.9 - (external) wood structural element consisting of two wood layers,

figa is a fragment of the wood structural element shown in Fig.9, in an enlarged image,

Fig.9b is a fragment of the wood structural element shown in Fig.9, before the joining of two wood layers,

figure 10 - laying of two adjacent to each other wood layers or, respectively, blanks adjacent to each other wood layers at the wood structural element shown in Fig.9,

11 - (internal) wood structural element consisting of four wood layers,

figa - wood structural element shown in Fig.11, in an enlarged image, provided with a layer of chip carpet on one side,

Fig - schematically the dimensions of the wood structural element shown in Fig.9 or 11, respectively

Fig - opposite location of the outer and inner wood structural element at a distance from each other before filling the intermediate space with a placeholder,

figa - the location shown in Fig.13, in an enlarged image,

Fig.14 - the arrangement shown in Fig.13, now with the filler filled with an intermediate space between the wood structural elements,

figa - arrangement shown in Fig.14, in an enlarged image,

Fig - wood wall block proposed by the invention, without grooved wood structural elements, in perspective view, and

Fig - wood wall block proposed by the invention, with grooved wood structural elements, in perspective view.

Figure 1 shows the inventive composite element 1 in its essentially final embodiment. The composite element 1 consists of an external wood structural element 2, as well as an internal wood structural element 3 located at a distance from it, and a filler 4 is located between two wood structural elements 2, 3.

Preferably, the aggregate 4 is made in the form of an insulating material, for example, PU foam (polyurethane foam) is used, due to which the composite element has very good heat-insulating properties, and additional installation of insulation from the outside of the composite element is no longer required.

In the composite element 1 according to the invention, now both wood structural elements 2, 3 each have recesses 100 on their side adjacent to the filler 4, and these recesses are made in the form of grooves 100.

In the manufacture of the element according to the invention, the intermediate space 90 (FIGS. 13, 13a) between the wood structural elements 2, 3 is filled with aggregate 4, for example, foamed. Due to this, the filler also falls into the recesses of the wood structural elements that face the (space filled with filler) intermediate space. When the aggregate solidifies, then an extremely stable composite structure is formed from wood structural elements with aggregate. In this case, a self-supporting composite element is formed, which is easy to manufacture, and which can prevent the formation of heat / cold bridges, since there is no need for nails, screws and other things to connect two wood structural elements.

Using the following figures, the construction and manufacture of the composite element of the invention in one of the preferred embodiments are depicted in more detail.

As, for example, it is clearly seen from Figs. 9, 9a, 11, 11a, each of the wood structural elements 2, 3 consists of at least two wood layers, and in the shown embodiment, the outer wood structural element 2 consists of two wood layers 20 , 21, and the inner wood structural element 3 is made up of four wood layers 30, 31, 32, 33, so that the inner element 3 can also carry a higher load.

Wood layers 20, 21; 30, 31, 32, 33 of each wood structural element 2, 3 on its upper and lower side 200, 300; 201, 301 are provided with grooves 100, which respectively extend along the entire upper or respectively lower side, the grooves of one wood layer being parallel to each other. One separate such layer is depicted in FIGS. 7 and 7a. As you can see, the grooves do not extend in the longitudinal direction of the wood layer, but extend across the longitudinal extent of the wood layer.

In order to be able to make the grooves in the wood layers as deep as possible, it is provided that the grooves 100 on both sides 200, 300, 201, 301 are offset from each other in a direction transverse to the longitudinal direction of the grooves 100, as is clearly seen in FIG. 4, which will be discussed below in more detail.

As also shown in FIGS. 9, 9a and 11, 11a, it is preferable if the grooves 100 of two adjacent wood layers 20, 21; 30, 31, 32, 33 extend laterally, at an angle α greater than zero relative to each other, and then the grooves 100 of the two wood layers 30, 31, 32, 33, which are separated by the wood layer 31; 32 run parallel to each other.

Typically, the angle α between the grooves of adjacent wood layers is from 60 ° to 120 °, preferably about 90 °.

From the point of view of manufacturing by machine, it was preferable if the wood layer 20, 21; 30, 31, 32, 33 is formed from several parallel elongated blanks 60.

Figure 2 shows non-planed wooden boards 50, for example with a thickness of 2-3 cm, a width of 8-15 cm, and a length of approximately 310-500 cm

To obtain blanks 60 (FIGS. 5, 5a, 6), these wooden boards 50 are planed and longitudinally slotted on their upper and lower sides, so that wooden boards 51 are provided with grooves 100 (FIGS. 3, 3a).

Figure 4 shows how the grooves 100 of the upper and lower sides are offset relative to each other in the width direction, that is, perpendicular to the longitudinal direction of the wooden boards 51, so that the grooves can be deep in the wood.

Now grooved wooden planks 51, depending on the angle (90 ° -β), under which they are laid relative to the longitudinal direction (see arrow in Fig.6) of the endless wood structural element, are cut obliquely at its two ends (this produces a waste 52) so that blanks 60 are obtained (FIG. 6).

To form a wood layer, as in FIG. 7, now a certain number of blanks 60, as shown in FIG. 8, are laid parallel to each other and their side surfaces close to each other (the upper side and / or lower side have recesses / grooves), preferably butt to each other.

After the grooves 100 extend in the longitudinal direction of the blanks 60 (which corresponds to the longitudinal direction of the wooden boards 51), the grooves are also inclined at an angle (90 ° -β) to the longitudinal direction (production direction of the endless element).

To obtain a wood structural element 2, as shown in FIGS. 9, 9a, now, as shown in FIG. 10, a second layer of blanks 60 is laid, which are inclined with respect to the longitudinal direction at an angle of the same size, but with respect to the opposite boundary surface, so that the blanks 60 or grooves 100 of two wood layers 20, 21 located one above the other at an angle α, which is not equal to 0 °, “intersect”, i.e. pass across (diagonally) to each other (there is no actual intersection, since the grooves pass in different layers). Both wood layers 20, 21 are glued together again.

In FIG. 9b, it is possible to see how the grooves 100 of the different wood layers 20, 21 extend “diagonally” with respect to each other, as described above.

The wood structural element 3, as shown in FIG. 11, is obtained when, for example, the two elements 2 shown in FIG. 9 are glued together, while adjacent wood layers have diagonally extending grooves. (It is also possible, of course, to sequentially lay down individual layers, but with an even number of wood layers, the above procedure is more effective).

When the boards at an angle equal to 45 ° (90 ° -β = 45 ° ⇒β = 45 °) are glued together to obtain an infinite element (figure 10), and accordingly, the blanks of two adjacent wood layers are located relative to each other 90 ° above each other other (for example, in 2 or 4 layers respectively) and thus are glued together, the wood structural element has maximum mechanical strength and stability. The wood structural element is made in the form of an endless element, i.e. the wood structural element has a certain width b and thickness, and with respect to its longitudinal extent (production direction) is made “endless” and cut into the desired length l of the wood structural element. Examples of dimensions are b = 2.60-3.00 m, l = max. rounded 12 m.

When using a composite element as a house wall, for example, the width b then corresponds to the height of the wall, the length l to the length of the wall.

For an external wood structural element, usually a thickness (height) of about 5 cm (2 wood layers) and about 10 cm for an internal wood structural element 3 (4 layers) is obtained.

With the practical preferred width of the wood structural element, this requires a maximum length of the blank board of approximately 500 cm. If only shorter boards are available (at least 310 cm with the preferred width), the exact same element production on the production line is possible, but the angle the boards relative to each other should then lie between 30 ° and 60 °. In this case, the angle between adjacent wood layers also changes (60 ° -120 °), which reduces the mechanical strength of the wood structural element. But in this way, targeted control of the strength of the wood structure is also possible.

In the next working step, on the inner side (the side in the building facing inward) of the internal wood structural element 3, a layer 70 (Fig. 11a) of the chip carpet is applied (by lamination), which has the effect of inhibiting steam. On the outside of the outer wood structural element 2, a layer 71 of a chip carpet is applied, open for diffusion.

Then the outer and inner (usually flat) wood structural elements at the desired distance a (for example, about 15 cm) are preferably parallel to each other, for example, are held in a certain position by means of a suitable machine (Figs. 13, 13a), and the intermediate space filled with aggregate (e.g. PU foam) (foams). In this case, in the example shown, a wall thickness of approximately 30 cm is obtained (fig. 14, 14a).

Foaming is carried out, for example, by a double strip (endless process), i.e. with the parallel movement of two bands.

Foam also fills the grooves 100 facing it, of each of the innermost wood layers 20, 33, due to which an extremely strong adhesion of the aggregate 4 with the wood structural elements 2, 3 is formed, while the other grooves are not filled with aggregate.

In order not to weaken the structure of the tree, it is preferable if in the placeholder 4 channels, voids and the like are provided for installation work and the like. It is also the preferred option in terms of ease of manufacture.

For example, substitutes (pipes) can be laid before foaming, or channels can be milled or drilled in the filler after foaming.

After that, the outer surfaces of the composite elements are plastered with plaster, which is open for diffusion, for example, plaster based on synthetic resins or, respectively, based on silicone resins, the inner sides of the walls and the lower sides of the ceiling are putty and coated.

The composite element proposed by the invention is a self-supporting, highly heat-insulating element of the floor, walls and ceiling of light construction, which, in particular, is intended for use in the construction of houses from finished parts.

The composite element is made of sandwich construction. It does not require any supporting inserts, reinforcements, etc., since the composite element in its entirety, i.e. Due to its composite structure of internal and external wood structural element with aggregate, it is a bearing.

In the composite element, then, depending on the need, openings are provided for windows, doors and other things, in which, before installation of the building, composite windows, doors, etc. are installed from the composite elements. These elements (windows, doors, ...) can, of course, also, if it is more preferable, be mounted only after the installation of the building from composite elements.

Particularly preferably, in particular, when both wood structural elements each have recesses on their side adjacent to the aggregate, and these recesses in the sides adjacent to the aggregate are also filled with aggregate, at least one, preferably each of the wood structural elements, respectively, consists of at least of two wood layers, and at least one of these wood layers of each wood structural element, which consists of at least two trees layers of layers, at least in separate areas and on both sides, provided with recesses, and the wood layer of the wood structural element that borders the aggregate, at least on its side facing the aggregate has recesses, or two or more wood layers each wood structural element, which consists of at least two wood layers, at least in separate areas and at least on one side provided with recesses, while that wood layer of wood to nstruktivnogo element, which borders the filler at least at its side facing to the core has a recess.

Thanks to foaming, in addition, bonding of the aggregate with wood structural elements is prevented, which makes it possible to more easily and quickly manufacture composite elements.

In particular, in the present invention, it is preferable if at least one, preferably each of the wood structural elements respectively consists of at least two wood layers, in each case, the wood layer facing the aggregate at least on its side facing the aggregate ( at least in certain areas) has recesses, but preferably this wood layer has recesses on two sides.

In addition, it is also preferable if one or more wood layers, preferably all, at least on one side, preferably on two sides (at least in separate areas) have recesses.

On Fig shows the first proposed by the invention composite element in the form of a wood wall block 1a. The wood wall block 1a consists of an external wood structural element 2a, as well as an internal wood structural element 3a located at a distance from it, with a placeholder 4a located between the two wood structural elements 2a, 3a.

In the embodiment of the wood wall block shown in FIG. 15, the wood structural elements 2a, 3a do not have a groove structure, such as that provided for in one of the more preferred embodiments, which is shown in FIG. 16.

FIG. 16 shows a wood wall block 1a ′ having substantially the same structure as the wood wall block 1a shown in FIG. 15, with the difference that the wood wall block 1a ′ in FIG. 16 has grooves 100 in wood structural elements 2a, 3a. These grooves 100 are important, in particular, on the surfaces facing the placeholder 4a of the wood structural elements 2a, 3a, but it is particularly preferred if the wood structural elements 2a, 3a have a grooved structure, as shown in FIG. 16. This grooved structure has already been explained in detail in FIGS. 1-14a.

A wood wall block, as shown in FIGS. 15, 16, has the following characteristic dimensions: width zb = 45 cm, height zh = 30 cm and thickness zd = 30 cm. But these data should be considered only as an example and explain the approximate size of the wood a wall block, which approximately corresponds to the size of a traditional brick (except, under certain conditions, thickness). But in principle, any dimensions of a wood wall block are possible, by means of a thickness zd, in particular by means of a filler thickness (insulating material), the insulating properties of a wood wall block can also be affected.

The wood wall block 1a, 1a ′ according to the invention is produced, as a rule, from one (large) composite element 1, which is shown in FIG. 1, for example, cut out. The characteristic, depicted in figure 1, the composite element 1 has dimensions in length and height, respectively, equal to several meters (2.6 m - 3 m height, length up to 12 meters). The wood wall block according to the invention is cut from one such (large) composite element 1 with the desired dimensions, and then the thickness of the wood wall block corresponds to the thickness of the composite element 1.

Composite elements 1 are used, for example, as wall elements for houses from finished parts. In this regard, it is particularly preferable from the point of view of manufacturing costs and environmental protection if the wall blocks are cut from the waste that is formed when cutting openings for windows and doors from the composite element 1.

Of course, wood wall blocks can also be directly manufactured to the desired dimensions without a detour through the large composite element 1, even if the “detour” through the large composite elements 1, as a rule, is a significantly more advantageous way.

When constructing a wall using the wood wall blocks proposed by the invention, these wall blocks in a known manner, as when using bricks, are stacked in rows on top of each other in layers. Wood wall blocks are glued together with a suitable adhesive, which is preferably applied thinly, over the entire surface and from all sides, i.e. wood wall blocks stick together not only in the upper and lower directions, but also on the side surfaces. Thanks to bonding over the entire surface and from all sides, reliable prevention of thermal bridges is possible.

In conclusion, the wall is plastered in a known manner from the outside, the inner sides of the wall, for example, are putty in a known manner and coated.

The composite element proposed by the invention is a highly heat-insulating element of light construction, which, in particular, is made with a sandwich construction.

Claims (21)

1. A composite element (1), including an external wood structural element (2), as well as an internal wood structural element (3) located at a distance from it, while a filler is located between two wood structural elements (2, 3) (4 ),
in this case, both wood structural elements (2, 3) each on their own side (200, 300) adjacent to the filler (4) have recesses (100), and the recesses (100) in the sides (200, 300) bordering the filler (4) also filled with aggregate (4),
characterized in that
at least one, preferably each of the wood structural elements (2, 3), respectively, consists of at least two wood layers (20, 21; 30, 31, 32, 33), while
at least one of the wood layers (20, 21; 30, 31, 32, 33) of each wood structural element (2, 3), consisting of at least two wood layers (20, 21; 30, 31, 32, 33 ), at least in certain areas and on both sides, provided with recesses (100), or
two or more wood layers (20, 21; 30, 31, 32, 33) of each wood structural element (2, 3), consisting of at least two wood layers (20, 21; 30, 31, 32, 33), at least in certain areas and at least on one side provided with recesses,
wherein the wood layer (20, 33) of the wood structural element (2, 3), which borders the aggregate (4), at least on its side facing the aggregate (4) (200, 300) has recesses (100),
moreover, the recesses are made in the form of grooves (100) substantially parallel to each other in wood structural elements (2, 3), in particular in wood layers (20, 21; 30, 31, 32, 33),
in this case, the wood layer (20, 21; 30, 31, 32, 33) is formed from several oblong preforms (50, 60) located next to each other, and all the preforms (60) of one wood layer have parallel grooves (100). 2. A composite element (1) according to claim 1, characterized in that the intermediate space (90) bounded by two wood structural elements (2, 3) is foamed with a filler (4), and the foam filler (4) connects two to each other after foaming wood structural element (2, 3). 3. A composite element according to claim 1 or 2, characterized in that the grooves (100) are located on the entire surface of the side (200, 300, 201, 301) of the wood layer (20, 21; 30, 31, 32, 33) or, respectively on the sides of the wood structural elements facing the placeholder. 4. A composite element according to claim 1 or 2, characterized in that each of the wood layers (20, 21; 30, 31, 32, 33) on at least one, preferably on both sides (200, 300, 201, 301 ) has grooves (100). 5. A composite element according to claim 1, characterized in that in the presence of grooves (100) on both sides of the same wood layer (20, 21; 30, 31, 32, 33) grooves (100) on both sides (200, 300, 201, 301) extend in the same direction with each other. 6. A composite element according to claim 5, characterized in that the grooves (100) on both sides (200, 300, 201, 301) are offset from each other in a direction transverse to the longitudinal direction of the grooves (100). 7. A composite element according to claim 1, characterized in that the grooves (100) of at least one wood layer extend transversely, at an angle (α) greater than zero relative to the grooves of another wood layer. 8. A composite element according to claim 1, characterized in that the grooves (100) of two adjacent wood layers (20, 21; 30, 31, 32, 33) extend transversely, at an angle (α) greater than zero relative to each other. 9. The composite element according to claim 8, characterized in that the angle (α) between the grooves of adjacent wood layers is from 60 ° to 120 °. 10. A composite element according to claim 8 or 9, characterized in that the grooves (100) of two wood layers (30, 32, 31, 33), which are separated by a wood layer (31; 32), run parallel to each other. 11. A composite element according to claim 1, characterized in that the grooves (100) extend in the longitudinal direction of the blanks (60). 12. A composite element according to claim 1, characterized in that the blanks (60) of adjacent wood layers (20, 21; 30, 31, 32, 33) extend across each other, at an angle (α) greater than zero, and the angle between blanks (60) of adjacent wood layers (20, 21; 30, 31, 32, 33) ranges from 60 ° to 120 °. 13. A composite element according to claim 1 or 2, characterized in that the aggregate (4) is an insulating material. 14. A composite element according to claim 1 or 2, characterized in that in the placeholder (4) channels, voids and the like are provided for installation work and the like. 15. A wood wall block (1a, 1a ′) formed from a composite element (1) according to one of paragraphs. 1-14 or respectively formed from part of the composite element (1) according to one of paragraphs. 1-14. 16. The use of a composite element according to one of paragraphs. 1-14 for walls, ceilings, floors or roofing of buildings. 17. The use of wood wall block under item 15 for the walls of buildings. 18. A building with at least one wall and / or at least one ceiling and / or at least one floor and / or at least one roof covering is at least partially formed by at least one element according to one of paragraphs. 1-14. 19. A structure in which at least one wall is at least partially formed by means of several wood wall blocks (1a, 1a ′) according to claim 15. 20. A method of manufacturing a composite element according to one of paragraphs. 1-14, including the following steps:
*) positioning of two wood structural elements (2, 3) at a distance from each other,
*) foaming of the intermediate space (90) formed by two wood structural elements (2, 3) with an aggregate (4) in the form of foam,
*) solidification of the aggregate (4),
in this case, before introducing the filler (4) on the sides (200, 300) of the two wood structural elements (2, 3) facing the intermediate space (90), recesses are made in the form of grooves (100), which simultaneously foam when the intermediate space (90) foams. . 21. A method of manufacturing a wood wall block (la, 1a ′) according to claim 15, comprising the following steps:
a) positioning of two wood structural elements (2, 3) at a distance from each other,
b) foaming of the intermediate space (90) formed by two wood structural elements (2, 3) with an aggregate (4) in the form of foam,
c) solidification of the aggregate (4),
d) cutting one or more wood wall blocks (la, 1a ′) from the composite element (1) obtained by steps a) to c),
in this case, before the introduction of filler (4) on the sides (200, 300) of the two wood structural elements (2, 3) facing the intermediate space (90), recesses are made in the form of grooves (100), which are foamed at the same time when foaming the intermediate space (90) .

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