RU2640624C2 - Lightweight construction slab and method of its manufacturing - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to a lightweight construction slab, in compliance with the restrictive part of paragraph 1 of the claim, to the use of lightweight construction slab to create the building shell, in compliance with the restrictive part of paragraph 10 of the claim; and to the method of manufacturing the lightweight construction slab, in compliance with the restrictive part of paragraph 11 of the claim. A lightweight construction slab (100) with a rectangular base shape and flatly interconnected layers (01, 02, 03, 04 …), each of which is formed by a plurality (20) of boards (2). The boards (2) of each layer (01, 02, 03, 04, …) on their lateral surfaces are connected with one another on the sides and on at least one principal surface (205, 205') have a plurality of grooves parallel to one another. The boards of the first and the second layer (01, 02) are oriented at a first acute angle (+α, -α) from 25 to 60° with respect to the longitudinal side surfaces (200, 200') of the lightweight construction slab (100). The boards (2) of the first layer (01) are oriented with respect to the boards (2) of the second layer (02) at an angle (2α). The lightweight construction slab (100) on at least two longitudinal lateral surfaces (101, 101') parallel to each other has at least one connecting tongue (102) and a connecting ridge (102') interacting with it with the form closure, for connecting with the form closure on both sides with lightweight construction slabs (100) made in the same manner. Wherein the boards of at least one layer are connected at the sides to one another with the form closure through the tongue (202) and the ridge (202), and the boards (2) of at least one layer (01, 02) located in the middle stratum (Ml) on both sides (205, 205') or, respectively, on both main surfaces (205, 205') are equipped with a first and a second plurality of grooves (3, 3') crossing one another at angles (γ) from 5 to 100°, the grooves of each plurality passing parallel to one another. The application of a lightweight construction slab and the method for manufacturing a lightweight construction slab are also described.

EFFECT: finding a simple solution, by means of which it is possible to make lightweight construction slabs having no tensions, if possible, with a sufficiently high elasticity and a high residual strength at strong bending; the possibility for applying the lightweight construction slabs in buildings in places subject to earthquake hazards should be ensured.

13 cl, 19 dwg

Description

The invention relates to a light building board, according to the restrictive part of paragraph 1 of the claims, to the use of light building boards to create a building housing, according to the restrictive part of paragraph 10 of the claims, and to a method of manufacturing a light building board, according to the restrictive part of paragraph 11 of the claims.

This invention relates to the field of new lightweight wood-based building boards, which are formed with a plurality of layers connected on the surface to each other, which are formed by means of sets identical to each other in one layer, but oriented in different layers at different angles to each other adjacent to each other on the sides, connected to each other by their lateral surfaces and provided with a plurality of plank grooves, and which are used for the manufacture of furniture, however, in particular, for quick raising simple and cheap, in particular, additionally damping sound and / or noise, erected in a simple manner with low costs for tools and personnel of buildings of various kinds, such as buildings, huts, sheds, exhibition halls, etc.

A wide variety of building boards and structural elements made of wood for various purposes are already known, which are made using a plurality of layers flatly adjacent to each other having hollow spaces, in particular grooves or the like, boards. Regarding the manufacture of grooved boards used for new lightweight building boards, reference can be made, by way of example, and not exclusively to Austrian patents Nos. 503236, 505486, 505855, 507231 and 508154, and also, for example, to DE 9408382 U1, respectively, WO 95 / 32082 A1.

A wooden structural element with layers connected to each other is known from WO 95/32082 A1, the layers being made of boards, which have grooves on the surfaces facing each other. The boards of the two layers immediately adjacent to each other are oriented across each other, respectively, diagonally. In accordance with this, also the grooves of these two layers are oriented diagonally to each other. It has been found that large internal stresses can occur in finished wooden structural elements, which can cause deviations from the desired flat shape in the wooden structural elements. In addition to this, these wooden structural elements are not sufficiently elastic and do not also have high strength, so that with one-sided clamping, the load capacity to failure is only small.

The objective of the invention is to find a simple solution with which it is possible to produce lightweight building boards that are as stress-free as possible with sufficiently high elasticity and high residual strength with strong bending. In particular, it should be possible to use lightweight building boards in buildings in earthquake-prone areas.

The problem is solved using a lightweight building board with the features of paragraph 1 of the claims, respectively, the use of this lightweight building board for the construction of a building building, according to paragraph 10 of the claims, and the method of manufacturing a lightweight building board according to claim 11. The dependent claims indicate alternative, respectively, preferred embodiments that solve other problems.

When solving the problem, it was found that with maximum freedom from stresses, high elasticity and with deformation exceeding the elastic deformation range, if necessary, achieve high residual strength when the boards of at least one layer of the middle layer of a lightweight building plate on both sides, in particular on both main surfaces are provided with a first and second set of grooves intersecting each other at angles (γ) of 5 to 100 °, preferably 7 to 20 °, while the grooves of each set are parallel But to each other. This ensures that on the outer sides of these layers long bridges cannot form in the direction of the fibers of the boards. Short, constantly interrupted jumper zones do not emit stress, even with large differences in humidity in a lightweight building board.

Since another layer is glued onto this at least one layer of the middle layer with the grooves open to the middle layer, preferably with two intersecting sets of grooves, the adhesive joints are narrowly defined zones in which the short bridges of the two connected layers protruding between the grooves are adjacent to each other. There is no glue layer having a large surface, which could limit the permeability to moisture in an undesired way perpendicular to the large outer surface of a light construction board. Around narrowly bonded adhesive joints with short jumpers there are hollow spaces formed by grooves. When bending forces act on a lightweight building board, this does not lead to the sudden destruction of the lightweight building board when the elastic limit is exceeded, but rather a local deformation of the connected short jumpers into compressible hollow spaces. These small internal deformations and fractures, respectively, crosses can absorb a lot of energy, without destroying the lightweight building board. Therefore, the lightweight building board according to the invention, also after a large absorption of the strain energy and the accompanying large bending, still has a large residual bending strength.

For high elasticity and high residual strength, it is important that the layers are made with good adhesion. For this, the boards of at least one layer, but preferably all layers, are connected to each other on the sides on their lateral surfaces with a geometric closure using a tongue and groove. These joints between adjacent boards of the same layer ensure that the layer does not collapse along the joints between the boards with a large bending load, and the applied bending energy is absorbed using the above deformations in the bridges. The different orientation of the boards of different layers also contributes to strength. The joints in the tongue and groove between the boards of one layer have the additional advantage that the layers, after gluing the side surfaces of the boards, are more likely to be loaded and the boards of the layer pass flush in the same plane.

By combining the features of the invention, an effect is achieved that exceeds the sum of the individual actions.

The subject of this invention is a multilayer, in its main form, preferably elongated, rectangular, lightweight wood-based building board with layers that are flat connected to each other from a plurality of grooves parallel to each other and connected to each other on the sides of the boards.

The new multilayer lightweight building board is characterized, in particular, in that it is formed with at least two layers of a shape having the same shape as the main shape of the lightweight building board, flatly connected to each other, if necessary through an intermediate layer located between them, with many oriented at an acute angle from 25 to 60 °, in particular from 30 to 45 ° relative to the corresponding longitudinal side surfaces of the corresponding layer, respectively, of a light building board connected to the sides on both sides with each other with a geometric closure through the tongue and tongue of the elongated boards, while

- the boards of each of both layers are located obliquely to each other at an angle (symmetrical to the axis), respectively, both layers are rotated 180 ° around an imaginary axis,

- boards of each of both layers on both sides are provided with sets of intersecting each other at an angle of 5 to 100 °, in particular 10 to 75 °, parallel to each other grooves, and

- lightweight building board at least on its long, parallel to each other longitudinal side surfaces has at least one connecting groove and one interacting with it with a geometrical closure connecting ridge for connecting on both sides with a geometrical closure with equally made lightweight building plates.

As indicated above, in the simplest cases, a building board may contain only two layers of sets of obliquely arranged, having positive and negative angles of equal absolute value, provided with grooves of the boards, and it is significant that not only one is provided on the boards ( first) a plurality of grooves parallel to each other, but also another set of grooves parallel to each other that intersect with the grooves of the first set, it being preferable when the angles of intersection Groove closures have the above meanings.

It is usually provided that it is in the case of only a two-layer building board that it has a layer on at least one of its both outer surfaces, for example a damping sound and / or heat insulating layer, in particular of a natural material such as a cork, and that both layer of building boards are additionally connected to each other through an intermediate layer located between them, which, in particular, also consists of a damping sound and heat of natural material, such as, for example, cork.

In the framework of the present invention, in particular with respect to the substantially simplified manufacture of lightweight building boards according to claim 2, it is particularly preferred that their layers are made using obliquely arranged intersecting boards, which each have a plurality of grooves, which, however, are oriented essentially in the direction of the wood fibers, i.e. parallel to the side surfaces of the boards, and which intersect with many other grooves parallel to each other.

In another preferred and frequently used embodiment, according to paragraph 3 of the claims, it is provided that the aforementioned building slab is made so that at least one corresponding to at least one layer of the middle layer specified in paragraph 1 of the middle layer is flatly connected on both sides another layer, while in other layers long boards connected laterally to each other are oriented at a second acute angle (-β, + β) relative to the longitudinal side surfaces of the lightweight building board, and second second acute angle (-β) boards coupled to the middle layer bordering the reservoir layer has a negative value relative to the first angle (α) of the layer of boards, and different or the same absolute angle value.

In addition, it is particularly preferable when the new lightweight building board contains a middle layer with three layers.

The location of the grooves intersecting each other on both sides forming the corresponding layers of the boards, due to the mixing effect in the air there, ensures that no groove of air in the grooves is preserved in the grooves in any of the grooves, which is ensured in a very simple way, on the one hand, the effect of strong thermal insulation and, on the other hand, due to the location of the grooves, i.e. cavities, a building plate is formed, which is characterized by a significant reduction in specific gravity, and in addition to this, due to the lower weight, the possibility of simple and lesser application of forces is also provided, i.e. without special lifting tools, handling the so lightweight construction board.

What is very significant in this new type of lightweight building boards is that due to simple joining with each other, it is possible to ultimately create significantly larger wall and ceiling elements, which are naturally also lightweight and at the same time high thermal and sound insulation, so they can be used to erect, in particular, structures in regions with large temperature differences between day and night, as well as in winter and summer, i.e. in areas with difficult climatic conditions.

It is particularly preferable, in particular, for the construction of buildings in areas with high heat and cold, that the slab is formed, for example, with several layers of a building slab, from a corresponding plurality of flatly connected to each other, if necessary through an intermediate layer, layers with connected on each side with a friend having overlapping grooves of boards that are oriented at an angle relative to the side surfaces of a lightweight building board, with the boards of the respective adjacent, respectively, coordinated d with the other layers are located obliquely to each other symmetrically to the axis, i.e. have, for example, positive and negative angles with respect to the side surfaces of the layers.

It is especially advisable in the framework of the invention, when it is ensured that the grooves of each of the boards intersecting each other forming together a lightweight building board of layers, preferably having a rectangular cross section, are at the same distance from each other and / or are made with the same width and either the same or different depth, and are surrounded by equally large parallelogram-shaped flat islands, while the surfaces occupied by the grooves in general have a ratio with the sum of the islands from 1: 2 to 2: 1, in particular from 1: 1.50 to 1.50: 1 and preferably from 1.25: 1 to 1: 1.25.

The connection between the layers is achieved preferably by means of adhesive joints between adjacent partial surfaces having parallelogram-shaped flat islands. Using the above relations between the surfaces occupied by the grooves and the sum of the surfaces of the islands, it is ensured that the adjacent partial surfaces are large enough for the desired connection. Since adhesive joints are limited to adjacent partial surfaces, a good moisture exchange can be achieved through a lightweight building board. Nowhere is a continuous adhesive layer acting as a barrier to moisture.

In particular, the lightweight building boards according to the invention have higher strength, in which one plurality of grooves are formed on the main surfaces of each of the planks of each or all layers of the lightweight building board connected side by side by means of parallel grooves which have essentially longitudinal passage coinciding with the passage of the board fibers, and the grooves along the fibers intersect at an angle with the grooves of the corresponding other plurality of grooves.

In another preferred embodiment, a layer of boards is located on at least one outer surface of the light building board, which only contains at least one plurality of grooves on the main surface of the light building board, but preferably two intersecting at an angle of 5 ° to 100 °, in particular from 7 ° to 20 °, a plurality of grooves. Preferably, the plurality of these grooves has a substantially longitudinal longitudinal passage coinciding with the passage of wood fibers of the boards. On their outward facing main surface, the boards contain milled edge zones, respectively chamfers, along both lateral lines. When a lightweight building board with boards with outward milled edge zones, respectively chamfers, is used as a wall element, the milled edge zones, respectively chamfers, pass in the form of small grooves obliquely inward and thereby can drain rainwater falling onto the corresponding board in a controlled manner to the side, which prevents different wetting and thereby different fouling, respectively, different coloring of the upper and lower zones of the wall.

It was found that for enhanced thermal insulation and sound insulation, it is preferable when the boards of the individual or all layers connected to each other on at least one main surface have a plurality of grooves parallel to each other and to the lateral surfaces of the boards, with grooves provided on both sides of the matched with each other depth, while the bottom of the grooves along the width of each of the boards is located continuously, for example, wavy, respectively, along the wave line, and these having different Loubinoux grooves intersect the grooves of another set.

Due to such a wavy arrangement of the bottom of the grooves, if necessary, that in separate places the grooves intersecting each other reach the other side of the boards, so that there is a passage from one main surface to the other main surface of the boards. A significant effect of the wavy arrangement of the bottom of the grooves is that due to this, it is especially good if necessary to prevent possible warping of individual boards.

As already mentioned briefly above, in particular with respect to the damping ability of new lightweight building boards, it is particularly preferred when at least one of the two outer surfaces formed by layers of lightweight building boards flatly connected to each other is flatly connected to having, in most cases, substantially a different thickness than the layers of the boards, the outer plate, preferably of natural insulating material.

In particular, regarding the simplicity, speed and effectiveness of the construction, as well as, in particular, the stability and durability of buildings made of lightweight building boards formed using layers of boards with grooves, according to the invention, for example, when used in developing countries, another subject of this is significant of the invention, namely, a slab-shaped lightweight structural element, in particular, a lightweight wall or ceiling element, and, in particular, a building body formed by means of a plurality of these elements, which It is characterized by the fact that it is formed, as indicated above, by means of a plurality of interconnected with each other with a geometric closure on their side surfaces into a tongue and groove of light building boards, while this connection to each other is carried out using at least one, however, preferably several, for example, located at a distance from each other and, if necessary, intersecting with each other, connecting and pulling together the light structural elements of the side walls forming the building’s casing, intermediate walls, floor and / or ceiling, adjustable in terms of pulling force, stretched by several, preferably by a maximum of 8 cm, tie straps. As for the coupling elements themselves, in one embodiment it is provided that they are formed by means of a strong spring connecting to each other both ends of the spring band, which, in particular, during vibrations, for example, due to earthquakes, leads to the building’s body not it is damaged because it provides a certain elasticity and the possibility of shifting wall elements relative to each other due to the deliberately limited ability to stretch the tie straps.

Due to the fact that lightweight building boards of the building’s hull do not stick together and their mutual stability is ensured by connecting them with a geometrical closure into the tongue and groove, if necessary, they can be disassembled without breaking or damaging the building boards, and then assembled in another place where necessary.

A very significant advantage of this invention is that all the auxiliary means necessary for the manufacture of boards and thereby structural elements, such as machine tools, and the work steps to be performed are so simple that they can only be completed by workers who have undergone short training, and the costs of the machines are minimal.

This is especially true for a lightweight building board according to claim 2, the boards of which have grooves parallel to the side surfaces.

A preferred method according to the invention for manufacturing a lightweight building board is characterized in that

- I. individual boards are smoothed, respectively, planed on the surface and provided on their both side surfaces with tongues and ridges interacting with each other with a geometric closure, then

- IIa. a plurality of adjacent adjacent to each other, obliquely oriented with a positive angle relative to the longitudinal direction of the feeding path, provided with lateral surfaces elements of geometric locking boards continuously pass through the device for milling grooves with two, preferably simultaneously cutting in both main surfaces of the boards parallel to each other inclined grooves with milling rolls,

-IIb. the boards so equipped on both sides with sets of inclined grooves parallel to each other are then again passed along the same or different feeding path, also resting on their sides to each other, under the same, however negative, respectively, opposite angle between the two cutting lots on both sides of the first intersecting cut grooves parallel to each other, otherwise inclined grooves by milling rolls,

- III. the boards so equipped on both sides with grooves intersecting each other after, for example, applying glue into the dowels and / or on their ridges, for example, are connected laterally to each other in a layer with a plurality of positive or negative inclined angles relative to the direction of their movement along board feeding paths

- IV. then, for example, in a wider guide, longitudinally straightening both sides of the layer edges is performed on both sides and cutting into separate layers having the desired longitudinal longitudinal rectangular base shape of the lightweight building board, after which

- V. layers with the special arrangements specified in claims 1 to 9, which form, in particular, a tongue and groove connection, are laid flat on top of each other either congruently, or preferably at least with a lateral parallel shift relative to each other, and beyond by applying pressure, for example, by means of a press (high pressure), they are glued together flat with each other to form a new lightweight building board.

Especially preferred is a substantially simplified embodiment of the new manufacturing method, which is characterized in that

- I. the boards provided for the manufacture of the layers are parallel to the direction of the feed path along this feed path, smooth out in one single operation, respectively, planed on the surface and provide elements interacting with each other with a geometric closure on both sides of the surface, namely, the tongue and a ridge, in their respective main surfaces located on both sides, respectively, of the two main surfaces, respectively, a corresponding plurality of parallel to each other, passing also parallel to the lateral surfaces of the boards, if necessary having at the wave-like passage along the width of the boards a different depth of the grooves 3, then

- II. in the boards so provided on both sides with sets of grooves parallel to the side surfaces of the boards, the boards cut off at an angle to the inclined ends, and having obliquely cut ends, the boards provided on both sides with the grooves at the same angle, pass laterally to each other along the other supply path under (specified ) the angle between the two, cutting parallel to the side surfaces of the boards, intersecting at an angle of the grooves located on both sides of the milling grooves rolls,

- III. so equipped on both sides of the grooves of the board intersecting each other after, for example, applying glue to the dowels and / or their ridges, for example, they are connected side by side to each other in layers with sets arranged obliquely at an angle with respect to the direction of their movement along the supply paths boards

- IV. polymer adhesive is applied to the main surfaces of the layers to be bonded to each other, and a polymer hardener is applied to their other main surface, and then

- V. layers with the special arrangements specified in claims 1 to 9, which form, in particular, a tongue and groove connection, are laid flat on top of each other either congruently, or preferably at least with a lateral parallel shift relative to each other, and beyond by applying pressure, for example, by means of a press (high pressure), they are glued together flat with each other to form a new lightweight building board.

As for the new manufacturing method, as well as preferably lightweight building boards made in such a way, the production can be carried out directly on site, i.e., for example, in the field of a disaster or earthquake, without high costs using short-trained workers without specially trained personnel, which is especially preferable in countries with small resources and, in particular, in case of increased or high danger from natural phenomena.

The following is a more detailed explanation of the invention with reference to the accompanying drawings, which depict:

FIG. 1 - four layers with boards adjacent to each other on the sides with grooves located on both sides, intersecting each other, in an exploded isometric view;

FIG. 2 - one of the new lightweight building boards of boards, in a plan view;

FIG. 3 is a section through a specially constructed building board with grooves on one of its both main surfaces with different depths of the bottom of the grooves,

FIG. 3a is a section of a differently made board;

FIG. 4 is a part of the invention according to the invention, formed by four layers of adjoining boards of a light building board, showing tongues and ridges for connection with other light building boards;

FIG. 5 - connection of lightweight building boards, according to the invention, into the building casing and holding them together with the use of tie tapes used in accordance with the invention;

FIG. 5a - constriction of the building with the help of several coupling tapes,

FIG. 6 is a diagram of a new and in itself relatively simple method for manufacturing grooved boards and new lightweight building boards formed from them, according to the invention;

FIG. 7 is a comparatively simpler preferred embodiment of a manufacturing method according to the invention;

FIG. 8 is a possible, particularly preferred embodiment of a coupling tape provided according to the invention;

FIG. 9 is a part of a layer with protruding jumpers in the form of surfaces in the form of a parallelogram between two sets of grooves, in a plan view;

FIG. 10 - surfaces for applying glue between two adjacent jumpers of two connected layers, according to FIG. 9,

FIG. 11a – 11e — layers of a light construction slab in an isometric view; and

FIG. 12 and 13 are lightweight building boards with three, respectively, five layers, according to FIG. 11a – 11e.

In FIG. 1 shows, in an exploded isometric view, four layers 01, 02, 03 and 04 of a building board 100 according to the invention, these layers being formed by boards 2 which are inclined relative to the side surfaces, respectively, of the sides of said layers, respectively, of the building board 100 and provided on both sides with grooves 3, 3 ′ intersecting each other.

Each two layers 01, 02, and 0.3 and 04 of the new building board 100, which are related to each other and thereby protected from warping, are formed by means of boards 2, which are oriented obliquely with respect to the lateral edges of the layers, however, the boards corresponding to each other layers 01, 0.2, and also 03, 04 are arranged obliquely to each other with rotation around the axis A1 by 180 °, i.e. the boards of layer 01 are oriented at an angle + α, and the boards of layer 02 at an angle –α relative to their lateral edges, respectively, of the side surfaces 200, 200 ', and the boards of layer 03 are oriented at a negative angle -β, and the boards of layer 04 at a positive angle + β relative to the respective lateral edges of these layers.

Both major surfaces of these layers and their boards 2 are indicated by 205 and 205 'and form together shown in FIG. 1, a four-layer system of a lightweight building board 100 according to the invention, in this case both layers 01 and 02 form the middle layer Ml, and in addition, it may be provided that between these two layers 01 and 02 an intermediate layer 001 of plugs, and in this case, naturally, in addition between layers 01 and 02, as well as 03 and 04, such an intermediate layer can be located and, in addition, naturally, on the outside, i.e. on the front outer surface 205 of the building board 203 and on the inner outer surface 205 ′ of the building plate 04, another (outer) layer may be arranged, for example, for applying plaster or an insulating layer, for example, from a cork.

Naturally, any other arrangement and number of layers of a new lightweight building board can be provided when it is only necessary to ensure that the respective layers interacting with each other are inclined relative to each other with the same positive and negative angle of the plurality of boards.

In FIG. Figure 2 shows, with the same positions remaining, one of the 100 boards 2 used in the new lightweight building board, which, when placed next to each other, form the corresponding one of the layers 01–04. It is shown that the corresponding lateral surfaces 200, 200 'of the boards 2 are provided in this case with a right rectangular tongue 202 and a left crest 202' entering with a geometrical closure in this tongue 202, while the sides 205, 205 'of the boards are provided with intersecting grooves 3 , 3 '.

The grooves 3, 3 'preferably have a rectangular cross-sectional shape and form between them the corresponding parallelogram-shaped, respectively rhombus-shaped islands 30 with the intersection angle of sharp angles γ. It should be noted that the boards 2, of course, can have tongues and ridges 202, 202 'intended for geometrical closure, not only on their side surfaces 200, 200', but also on their short, not particularly marked end surfaces.

In FIG. Figure 3 shows, while retaining the notation with the same positions, the cross section of one of the layers 01–04 of the boards 2 forming as a whole, the grooves 3, 3 'having a rectangular cross-sectional shape here are shown both on the upper and lower sides of the board 2. The on the lower side 205 ', the grooves 3 or 3' are in the form of a plurality of grooves oriented parallel to the longitudinal side surfaces and parallel to each other, and they intersect with another set of grooves not shown. The grooves 3 or 3 'of the lower side 205' have a depth tn different from each other, while these groove bases are made along a continuous wave line with different depths across the board 2.

In FIG. 3a shows, with the same positions remaining, the preferred embodiment of cut 200 parallel to each other and side surfaces of the boards 200, 200 ′ of the boards 2 layers 01–04 in their both main surfaces 205, 205 ′ of the grooves 3, while the depth of the grooves in the upper and lower grooves is matched and it is different with the formation of a wave line along the width of the board 2. These sets of grooves 3 parallel to the lateral surfaces of the boards of the boards intersect at an angle not shown by the sets of grooves 3 'parallel to each other, 205', 205 'located on each side, n and wherein these inclined grooves 3 'also extend parallel to each other on both sides 205, 205' board 2.

In FIG. 4 shows, while remaining at the same positions, the upper zone of the lightweight building board 100 according to the invention, in general, with four layers 01-04 flatly connected to each other, which, as shown on one of the layers, are formed by obliquely oriented, connected on the sides each other boards 2, while these boards 2 have grooves 3, 3 ′ intersecting each other on both sides. Layers 01–04 are laterally offset relative to each other and thus form at least one connecting tongue 102 and a crest 102 ′, etc., which makes it possible to extremely stably connect these layers and thereby the building board 100 s two next, adjacent on both sides of the same building boards 100, without the need for lateral gluing them to each other.

In FIG. 5 shows, with the same positions remaining, a part of the building building 10, which is formed from elongated lightweight building boards 100 which are connected to each other with a geometric closure, which are formed by means of planks 2 inclined along the length of the boards, and these boards have on both sides grooves 3, 3 ′ intersecting each other. This building case 10, in this case having a square quadrangular shape, is connected not by laterally gluing the building boards 100 to each other, but by means of a tension tape 150 which is purposefully pulled together around the building case 10, which in turn is provided with a spring along its length and provides the possibility of a certain shift, for example, caused by the expansion or shrinkage of wood due to changing humidity or in the event of an earthquake, a certain small shift of building slabs t 100 relative to each other, without consequences or even destruction due to this building building 10.

In FIG. 5a schematically shows the screed according to the invention, a building with a gable roof, with three tie straps 150 being laid and pulled together, for example vertically through the bottom plate 81, two opposite side wall elements 82 and both flat roof elements 83, and two tie rods the tapes 150 hold the side walls, while for each of the individual sections of the tie-tape laid over the edges for each of the flat elements of the building, it is separately regulated depending on the expected loads, for example, in the case of an earthquake clamping element 9.

In FIG. Figure 6 shows, with the same positions remaining, a simple and problem-free on-site method of manufacturing the lightweight building board 100 explained in detail above, it being envisaged that in stage IIa, a plurality of adjacent side to each other, obliquely oriented with a positive angle relative to the longitudinal direction the feed path (6), previously provided with a tongue and tongue on both side surfaces in stage I on both side surfaces for geometrical closure of the boards (2), is continuously passed through the device (61) for milling the channel wok with two, preferably simultaneously cutting in both main surfaces (205, 205 ') boards (2) parallel to each other grooves (3) with milling rolls (62, 62'), which is in another stage

- IIb. so equipped on both sides with sets of intersecting grooves (3) parallel to each other, the boards (2) are then passed again along the same or another feeding path (6 ') also with an adjoining side to each other, under the same, however negative , respectively, the inverse angle between the two grooves intersecting the first cut grooves parallel to each other grooves (3 ') by milling rolls (62, 62'), which is at the stage

- III. the boards (2) so equipped on both sides with grooves intersecting each other (3, 3 ′) after, for example, applying glue (K) to the point in their tongues (202) and / or on their ridges (202 ′), are connected to the sides each other in a layer (04, 02, 01, 03) with sets located at a positive or negative angle of inclination relative to the direction of their movement along the feeding paths (6, 6 ') of the boards (2), which is then in another stage

- IV., For example, in a wider guide (60), preferably longitudinally straight-line cut-off on both sides (7) of the edges of the layer and cutting into separate layers (01–04) having the desired longitudinal rectangular main shape (100), after what is at the stage

- V. a polymer adhesive (Pk) is applied to one of the main surfaces (205, 205 ') of each of the layers (01–04) and a polymer hardener (Ph) is applied to the corresponding other main surface (205', 205), and that after this stage

- VI. the layers (01–04) with the arrangements indicated in claims 1–9 of the invention, forming, in particular, a tongue and groove joint, are laid flat on top of each other either congruently, or, as shown here, preferably with at least a lateral parallel shift relative to each other, and due to the application of pressure (P), for example, by means of a press (high pressure) they are glued flat to each other with the formation of a new lightweight building board (100).

In FIG. 7 shows schematically, while retaining the positions used for designating, particularly preferred in the framework of the invention, saving labor costs, work steps and equipment, an embodiment of the manufacturing method is also particularly preferred for the new lightweight structural elements 100 disclosed in paragraph 2 of the claims, it is provided that

- I. the boards (3) provided for the manufacture of the layers (01, 02, 03, 04) are parallel to the direction of the supply path (6) along this supply path (6), smooth out in one single operation, respectively, planed on the surface and supplied respectively, milled on their both side surfaces interacting with each other with a geometric closure, namely, the tongue (202) and the crest (202 '), respectively, are milled on their main surfaces (205, 205') located on both sides, respectively corresponding set of parall solid to each other, also parallel to the lateral surfaces (200, 200 ') of the boards (2), respectively, extending in accordance with the passage of wood fibers (vf) of the grooves (3), respectively, if necessary, having a wavy passage along the width of the boards (2 ) different depth (tn) of the grooves 3,

- II. in the grooves (3) provided on both sides of the planks parallel to the side surfaces of the planks of the boards, the boards (2) are then cut off at an angle to the inclined ends, and these having inclined cut ends, provided on both sides of the grooves (3) of the board (2) at the same angle, with lateral adjoining to each other, they pass along a different feeding path (6 ') at an (indicated) angle (α) between two grooves intersecting parallel to the side surfaces of the grooves (3) at an angle of the groove (3') located on both sides of the milling grooves rolls (62, 62 '),

- III. so provided on both sides of the grooves (3, 3 ′) that intersect each other with the grooves (2) after, for example, applying glue (K) pointwise to their side tongues (202) and / or to their ridges (202), they are connected to each other on the sides with the other in layers (01, 02; 01, 02) with sets located slanted at an angle relative to the direction of their movement along the supply paths of the boards (2), then

- IV. polymer adhesive is applied to the main surfaces (205, 205 ') of the layers to be bonded to each other, and a polymer hardener is applied to their other main surface (205', 205), and then

- V. layers (01–04) with the special arrangements specified in paragraphs 1–9 of the claims, forming, in particular, connecting dowels (102) and ridges (102 '), lay flat on top of each other either congruently or preferably at least with lateral parallel shift relative to each other, and due to the application of pressure (P), for example, by means of a press (high pressure) they are glued flat with each other with the formation of a new lightweight building board (100).

In FIG. 8 shows one of the possibilities for making the coupling elements 9 of the coupling tapes 150, with which it is possible to individually control the tension forces to be tensioned around the building body 10 along its edges and surfaces of the coupling tapes 150.

A spring body 90 is connected externally to both ends of separate sections of the tie strap 150, for example by rivets or welding. Between the housings 90 there is a middle nut 95 provided with a finger 94 with a right-hand thread and a finger with a left-hand thread 94 ', connected to them as a whole, and the coupling fingers 94, 94' are designed for screwing into both right-connected coupling nuts 92 and left-hand thread 941, 942, and thereby the springs 93 located in the housing 90 can more or less pull the tie strap 150.

In FIG. 9 shows part of the layer 01 of the middle layer Ml, while the portions of the two boards 2 are connected to the lateral surfaces 200, 200 'with a geometric closure using a tongue 202 and a crest 202'. The boards 2 of this layer 01 on both main surfaces 205 (205 ') are provided with a first and second set of grooves 3, 3' intersecting each other at an angle γ, while the grooves of each set extend parallel to each other, and preferably the distance between the grooves and the width The grooves for each set have an essentially constant value. In the illustrated embodiment, the first plurality of grooves 3 is oriented parallel to the side surfaces 200, 200 ′ of the boards 2. Thus, the angle γ corresponds to the angle between the side surfaces 200, 200 ′ and the orientation of the second plurality of grooves 3 ′. In the shown embodiment, the angle γ = 10 °.

Between the grooves 3, 3 ', islands 30 are formed with a parallelogram-shaped surface. The magnitude and, in particular, the length of these islands 30 depends on the distance between adjacent grooves 3, 3 'of each of both sets, as well as on the angle γ between the directions of both sets of grooves 3, 3'. When the angle γ decreases from 90 °, the length of the islands 30 increases, while the angle between the direction of the longest length of the islands and the side surfaces 200, 200 ′ decreases. At small angles γ, for example 10 °, the islands are portions of the bridges that extend approximately in the direction of the side surfaces 200, 200 ′. For a given distance between the grooves, the desired length of the jumper sections can be set by choosing the angle γ.

When the angle γ approaches 90 °, the islands become rectangular, and the length and width correspond to the distance between the grooves of each of the sets. When the angle γ changes from 90 ° to 100 °, then the rectangles go back into slightly elongated parallelograms, while they are formed mirror symmetrically with respect to parallelograms at angles γ less than 90 °.

In FIG. 10 shows blackened bonding adhesive surfaces, respectively, adhesive joints 30a that occur when the surfaces of two layers 01, 02, according to FIG. 9, are connected to each other using glue with a given relative orientation, while the adhesive joints 30a are shown only where they are in contact with each other through the adhesive surfaces of the zone of islands 30 of both layers 01, 02. The second layer 02 is rotated relative to the first layer 01 at an angle 2α, in accordance with this, between the side surfaces 202 of the first layer 01 and the side surfaces of the second layer 202 also lies an angle 2α. The bisector shown in the 2α angle corresponds to the A1 axis, which runs parallel to the longitudinal side surfaces of the lightweight building board. Accordingly, the boards 2 of the first and second layers 01, 02 are oriented with a first acute angle –α, respectively, + α relative to the axis A1, respectively, of the longitudinal side surfaces of the light construction board. In the shown embodiment, the angle α = 52 °, and thus the angle between the boards 2 of both layers 01, 02 is 104 °.

Adhesive joints 30a are narrowly limited zones of islands 30 protruding opposite to each other. An angle of 114 ° lies between the directions of the longest lengths of islands 30a of both layers 01, 02 in the shown embodiment. When the intersecting grooves 3 ′ of the first and second layer are opposite to each other, i.e. oriented with an angle γ = -10 ° and with an angle γ = + 10 ° relative to the corresponding side surfaces 200, 200 ', the angle between the direction of the longest length of the islands 30 of both layers 01, 02 is 84 °. The directions of the longest length of the islands 30 of both layers 01, 02 can be chosen so that they extend essentially perpendicularly, respectively across each other. With the selected length, the islands 30 of the first layer 01 overlap essentially eight islands 30 of the second layer 02. Due to the adhesive joints 30a, the islands of both layers 01, 02 together form a kind of connecting grid, the connecting length of which can be selected using the length of the islands 30.

Around narrowly limited adhesive joints 30a with short islands 30, respectively, of jumpers there are hollow spaces formed by grooves 3, 3 '. When bending forces act on a light building board, they do not lead to the sudden destruction of the light building board when the elastic limit is exceeded, but the connected islands 30 are only locally deformed into the compressible hollow spaces of the grooves 3, 3 '. These small internal deformations and breaks, respectively, crossing can take a lot of energy without breaking the lightweight building board. Therefore, a lightweight building board, even after perceiving a large deformation energy and the accompanying strong bending, still has a large residual strength. The specified lattice structure can be selected using the angles γ, α and the distance between the grooves so that it in all directions provides similar characteristics of elasticity, stability and deformation.

In FIG. 11a – 11e show boards 2 for three, respectively, five layers of a light building board 100, according to FIG. 12, respectively 13. All boards 2 contain a tongue 202 and a crest 202 'on the respective lateral surfaces and thereby for all layers of the light building board 100. The boards 2 of the adjacent layers are oriented at an angle 2α relative to each other.

In FIG. 11a and 11e show the corresponding board 2 for one outer surface of the light building board 100, while these boards 2 only on the inwardly directed light building board 100 of the main surface contain two sets of intersecting grooves 3, 3 '. One set of grooves 3 has a longitudinal length substantially coinciding with the passage of wood fibers, respectively, of the side surfaces of the boards. On their outwardly lightweight building board 100 of the main surface, these boards 2 have edge zones milled along both side lines, respectively chamfers 2a.

In FIG. 11b – 11d show the corresponding board 2 for one layer of the middle layer Ml of the light building board 100. These boards 2 on both main surfaces contain two sets of intersecting grooves 3, 3 ′. One set of grooves 3 has a longitudinal length substantially coinciding with the passage of wood fibers, respectively, of the side surfaces of the boards 2.

The lightweight building board 100 according to FIG. 12 is made of three and the plate according to FIG. 13 consists of five layers with the above boards 2. Accordingly, the middle layer Ml of the light construction board according to FIG. 12 contains only one layer, and the middle layer, according to FIG. 13, contains three layers. Chamfers 2a pass in the form of small grooves obliquely relative to the longitudinal side surfaces of light building elements.

Claims (24)

1. Lightweight building board (100) with a rectangular basic shape and layers (01, 02, 03, 04 ...) flat connected to each other, each of which is formed by a plurality of (20) boards (2), with each board (2) layers (01, 02, 03, 04 ...) on their lateral surfaces are connected to each other on the sides and at least on one main surface (205, 205 ') have many parallel grooves, boards of the first and second layer (01, 02) are oriented at a first acute angle (+ α, -α) from 25 to 60 ° relative to the longitudinal side surfaces (200, 200 ') of a light construction slab you (100), boards (2) of the first layer (01) are oriented relative to the boards (2) of the second layer (02) at an angle (2α), and a light building plate (100) on at least two parallel longitudinal sides ( 101, 101 ') has at least one connecting tongue (102) and a connecting ridge (102') interacting with it with a geometric closure for connecting with a geometric closure on both sides with equally made lightweight building boards (100), characterized in that boards of at least one layer are connected along with each other with a geometric closure through the tongue (202) and the comb (202 '), and boards (2) of at least one layer located in the middle layer (Ml) (01, 02) on both sides (205, 205') or, respectively, on both main surfaces (205, 205 ') are provided with a first and second set of grooves (3, 3') intersecting each other at angles (γ) of 5 ° to 100 °, while the grooves of each set extend parallel to each other. 2. Lightweight building board (100) according to claim 1, characterized in that at least in one layer (01, 02) the middle layer (Ml) has on each of both sides (205, 205 ') boards of both side surfaces ( 200, 200 ') of the boards (2) the corresponding set of parallel grooves (3, 3') parallel or, respectively, extending essentially in the direction of the wood fibers, and this set of parallel grooves (3, 3 ') intersects at an angle of 5 to 50 °, in particular from 5 to 35 °, by a variety of other parallel grooves (3, 3 '), with other grooves (3 or 3') on both sides (205; 205 ') to run parallel to each other. 3. Lightweight building board (100) according to claim 1 or 2, characterized in that at least one other layer (03, 04) is flatly connected on both sides with at least one layer (01, 02) of the middle layer (Ml). ), while in other layers (03, 04), the elongated boards (2) connected laterally to each other are oriented at a second acute angle (-β, + β) relative to the longitudinal side surfaces (200, 200 ') of the lightweight building board (100 ), and the second acute angle (-β) of the boards (2) connected to the adjacent layer (01) of the middle layer (Ml) of the layer (03) is negative with respect to th angle (α) of boards (2) of the layer (01) and an excellent size or the same absolute angle value. 4. Lightweight construction board (100) according to claim 1, characterized in that the lightweight construction board (100) contains a middle layer with three layers (01, 02, 03). 5. Lightweight building board (100) according to claim 1, characterized in that at least two of the layers (01, 02, 03, 04 ...) are flat connected to each other through an intermediate layer (001). 6. Lightweight building board (100) according to claim 1, characterized in that the grooves (3, 3 ′) of the boards (2) intersecting each other are at the same distance from each other and / or are made with the same width and surround equally large the shape of the parallelogram is flat islands (30), while the surfaces occupied by the grooves (3) have a ratio with the sum of the surfaces of the islands (30) from 1: 2 to 2: 1, preferably from 1.25: 1 to 1: 1.25, and the grooves have, in particular, a rectangular cross section and are made with the same or, if necessary, with different Lubin. 7. Lightweight building board (100) according to claim 1, characterized in that at least on the outer surface of the lightweight building board there is a layer of boards (2), which is only on the inside of the lightweight building board (100) of the main surface (205) or 205 ') contains at least one set of grooves, however, preferably two sets of grooves intersecting at angles (γ) of 5 ° to 100 ° (3, 3'), preferably these grooves (3) have essentially the same passage fiber (vf) wood planks (2) longitudinal length and in particular, the boards (2) on their outwardly light building plate (100) of the main surface (205, 205 ') contain milled edge zones or chamfers along both long side lines. 8. Lightweight building board (100) according to claim 1, characterized in that the boards (2) connected on the sides to each other of at least one layer (01, 02, 03, 04) on at least one main surface (205 or 205 ') have a plurality of grooves parallel to each other (3 or 3') with different depths (tn), the bottom of the grooves being located across the width of each of the boards (2) essentially along the wave line. 9. Lightweight building board (100) according to claim 1, characterized in that at least one of both outer surfaces of the lightweight building board (100) has an outer layer or an outer slab, if necessary with a significantly smaller thickness than the thickness of the layers ( 01, 02) of the middle formation, preferably of natural insulating material, such as a cork. 10. The use of lightweight building boards (100) for the construction of the building (10) of a building, characterized in that lightweight building boards (100) according to any one of paragraphs are used. 1–9, while they are adjacent to each other with a geometric closure and held together with the help of connecting and coupling elements (9). 11. A method of manufacturing a lightweight building board (100) according to any one of paragraphs. 1-10, in which the layers (01, 02, 03, 04 ...) are formed from sets (20) of boards (2) and are flatly connected to each other, with at least one main surface (205, 205 ') of the boards (2) a plurality of grooves parallel to each other are milled, boards (2) of each layer (01, 02, 03, 04 ...) on their side surfaces are joined to each other on the sides, while boards of the first and second layer (01, 02) are joined with each other so that they are oriented at a first acute angle (+ α, -α) from 25 to 60 ° relative to the longitudinal side surfaces (200, 200 ') of the light building board (100), as well as the board (2) the first layer (01) are oriented relative to the boards (2) of the second layer (02) at an angle (2α), and at least two longitudinal side surfaces parallel to each other (101, 101 ') are made at least at least one connecting tongue (102) and a connecting ridge (102 ') interacting with it with a geometrical closure for connecting with a geometrical closure on both sides with equally made lightweight building boards (100), characterized in that the boards of at least one layer on their lateral surface at the sides are connected to each other with a geometric closure through a tongue (202) and a comb (202 '), and boards (2) of at least one layer located in the middle layer (Ml) (01, 02) on both sides (205, 205 ') or, respectively, on both main surfaces (205, 205'), the first and second set of grooves (3, 3 ') intersecting each other at angles (γ) of 5 ° to 100 ° are provided with grooves (3, 3 ') of each set are parallel to each other. 12. The method according to p. 11, characterized in that - I. individual boards smooth or plan on the surface and provide on their both side surfaces (200, 200 ') interacting with each other with a geometric closure with a tongue (202) and a crest (202'), then - IIa. a plurality of adjoining laterally to each other, obliquely oriented with a positive angle relative to the longitudinal direction of the supply path (6), provided on the side surfaces with elements (202, 202 ') of geometric closure of the boards (2) is continuously passed through the device (61) for milling grooves with two, preferably simultaneously cutting in both main surfaces (205, 205 ') boards (2) parallel to each other inclined grooves (3) with milling rolls (62, 62'), - IIb. thus provided on both sides with sets of inclined grooves (3) parallel to each other, the boards (2) are then passed again along the same or another feeding path (6 ') also with an adjoining side to each other, under the same, however negative or, respectively, the inverse angle between the two cutting on both sides of the plurality of first grooves intersecting the first cut (3) parallel to each other, the otherwise inclined grooves (3 ') by the milling rolls (62, 62'), - III. thus provided on both sides with grooves (3, 3 ′) intersecting each other with the boards (2) after, for example, applying glue (K) to the point in their tongues (202) and / or on their ridges (202 ′) side by side with each other in a layer (01, 02, 03, 04) with a plurality of boards located at a positive or negative angle of inclination relative to the direction of their movement along the supply paths of the boards (2) and then, for example, in a wider guide (60) straight-line longitudinal cutting on both sides (7) of the edges of the layer and cutting (7 ') on Suitable desired longitudinal rectangular basic shape of the light construction board (100) the individual layers (01-04), after which - IV. polymer adhesive (Pk) is applied to one of the main surfaces (205, 205 ') of the layers to be bonded to each other (01–04), and a polymer hardener (Ph) is applied to their other main surface (205', 205), and then - V. so prepared layers (01–04) with arrangements according to paragraphs. 1-9 with the formation, in particular, of connecting dowels (102) and ridges (102 '), are laid flat on top of each other either congruently, or preferably at least with a lateral parallel shift relative to each other, and due to the application of pressure (P) for example, by means of a press (high pressure) they are glued flat to each other with the formation of a new lightweight building board (100). 13. The method according to p. 11, characterized in that - I. the boards (2) provided for the manufacture of the layers (01, 02, 03, 04) are carried out parallel to the direction of the supply path (6), along this supply path (6) they smooth out in one single operation, in particular planing, on the surface, on their both lateral surfaces, they are provided with elements interacting with each other with a geometric closure, namely, a ridge (202 ') and a tongue (202), and in them located on both sides or, respectively, of both main surfaces (205, 205'), they perform or , respectively, milling the corresponding set to Navok (3) parallel to each other, as well as parallel to the side surfaces of the boards (2) or, respectively, passing in accordance with the passage (vf) of the wood fibers in the boards (2), if necessary having an approximately wavy passage along the width of the boards (2) different depth (tn) of the grooves (3), - II. in the grooves (3) of the boards (2) thus provided on both sides of the planks parallel to the side surfaces of the boards, the boards (2) are then cut at an angle to the inclined ends, and the inclined ends having the grooves (3) on both sides of the board (2) at the same angle, with lateral adjoining to each other, they pass along a different feeding path (6 ') at an angle (α) between two cutting grooves (3) intersecting parallel to the side surfaces of the boards at an angle of the groove (3') located on both sides by milling grooves (62, 62 '), - III. thus provided on both sides with grooves (3, 3 ′) intersecting each other with the boards (2) after, for example, applying glue (K) to the dowels (202) and / or their ridges (202 ′), for example, are connected on each side with each other in a layer (01, 02; 01, 02) with sets located slanted at an angle relative to the direction of their movement along the supply paths of the boards (2), then - IV. polymer adhesive (Pk) is applied to the main surfaces (205, 205 ') of the layers to be bonded to each other, and a polymer hardener (Ph) is applied to their other main surface (205', 205), and then - V. so prepared layers (01, 02, 01, 02) with arrangements according to paragraphs. 1-9, in particular with the formation of connecting dowels (102) and ridges (102 '), are laid flat on top of each other either congruently, or preferably at least with a lateral parallel shift relative to each other, and due to the application of pressure (P), for example, a press (high pressure) is glued flat to each other to form a new lightweight building board (100).

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