CZ20048U1 - Outer coverings of buildings - Google Patents

Description

Exterior facing of buildings

Technical field

The technical solution relates to a modular arrangement of the exterior cladding of buildings usable in the construction industry, made of wood-based material or its substitutes.

BACKGROUND OF THE INVENTION

In the construction industry, wood cladding or wood substitutes are used for various reasons. The tiles are made around various base bodies, of masonry, wood, panels or other materials.

Conventional building cladding consists of straight rectangular slabs without special shaping of the end portions that are charged horizontally on the perimeter around the building into prisms or subfloors, with the ends simply superimposed or stacked together. These cladding boards are flat, rectangular in shape and their ends either have straight walls perpendicular to the front wall or are cut obliquely, so-called miter. It is common for the tiles to have side edges straight or a groove, where a groove is formed on one side of the slab in the length direction and a step on the other. For technical and aesthetic reasons, the corner parts of flat panel cladding usually overlap with a molding or a corner molding. Often, the tiles are also laid by placing a prism vertically on the corners of the building, and the rectangular tiles are seated at their ends to the corner prism, so that the prism forms a corner cleaning.

A disadvantage of said cladding is that there is a relatively low strength in the cladding of the cladding joints at the corners of the buildings where the joints of the panels are present and sometimes undesirable loosening, even detachment, of the ends of the panels occurs. This is due to the fact that the wood material works and twists due to the constant variation of moisture and drying during the year and is due to the simple arrangement of the lining joints, which in no way supports the consistency of the result. Another disadvantage is the appearance of the result, where it is obvious at first glance that it is only a cladding and not a wooden building.

Classical wooden buildings, known as wooden houses, are built from beams and have dovetail joints in the corners. These joints are very strong, they are also tight and aesthetic. However, such joints are known only for beams. Corner shaping for dovetail joints on beams is made by cutting corner portions at the ends of the beams. However, beams are a material that is suitable for construction but is not very suitable for cladding around buildings. They have a high weight, which makes transport and handling considerably more difficult and usually requires heavy machinery. It is also a relatively expensive material. The beams are also not suitable for cladding around building insulation, because if the insulation panels and other beams are used, the wall thickness of the building and its circumferential dimensions would increase too much.

The essence of the technical solution

The disadvantages of the prior art are largely eliminated by the proposed technical solution. The exterior cladding of the buildings, designed as a modular system around the walls of the building based on flat wood panels or its substitutes, is solved. After assembling the modular system, the lining boards are laid at least at the corner locations of the building such that their longitudinal direction extends horizontally and at the corner locations there are the ends of at least some of the boards, referred to herein as corner ends. These corner ends of the panels, stacked together, form corners on the cladding building, respectively. corner edges, lining. The essence of the novel solution is that the corner ends of the plates are already provided with a double-sided corner recess in the state prior to the lining assembly, while the remaining narrower part of the plate is provided with an additional part fixed on the reverse side. as an extension of the end wall of the plate on the plate at an angle. The angle is formed relative to the surface of the back side of the plate. The recess is made over the entire thickness of the plate. The projection has sides at the end and sides. The corner of the lining is formed by alternating mounting on the narrower portions of the corner ends of the plates located on one side

The auvto knows the buildings and the projections of the plates located on the adjacent side of the building. The shape and dimensions of the faces and recesses are such that the faces and sides of the projections of the panels on one side of the building fit into the recesses of the panels from the side of the building.

The projection preferably has a height equal to the thickness of the plate up to 15 times the thickness of the plate.

The recess at the corner ends of the plate has an apex angle of 50 to 90 °, wherein the end walls of the plate in the recess, as well as the projection face, are preferably perpendicular to the longitudinal axis of the plate.

Preferably, the narrower portion of the plate is symmetrical, wherein the recess on both sides of the corner end of the plate is the same.

Preferably, the narrower portion of the plate extends symmetrically towards its end wall and the projection also extends symmetrically towards its face. This provides a dovetail fastening at corners that do not start.

It is essential for the proposed solution to pay attention to the direction of the fibers in the corner joints of the plates. The projection is preferably fixed to the board with its fiber direction in the same direction as the fiber direction of the board on which the projection extends. This creates a high-quality, strong joint.

Fibers of the same course do not tend to curl or loosen the projection in the finished lining as a result of alternating moisture and drying during the year. The cladding has optimal shape stability. The result is also aesthetically pleasing, because the visual appearance of the joint gives the impression of pivot joints from classic beams.

Advantageously, the projection consists of at least two rigidly attached pieces of material which prevent undesirable warping or corrugation of the material and increase the life of the lining joints.

Ideally, the protrusion is in the form of a ply and its pieces are also in the form of a ply, i.e., pieces of material bonded by means of an adhesive, close to one another without joints, due to the application of increased bonding pressure.

The panels for making this lining may be conventional panels. Preferably, the lining plates have the same thickness everywhere. They are not widened or tapered anywhere, especially not because of the corner joint, they have the same thickness on their portion without the projection as at the location of the projection.

The projection has a thickness ranging from the thickness of the plate to the length of the narrower portion of the plate.

The joint of the corner ends of the plates can advantageously be provided with at least one vertical connecting pin, in particular at the corners of buildings in mountainous weather conditions.

The proposed technical solution is suitable for lining from flat boards, but also from so-called perod groove. Advantageously, the tightness between adjacent plates can be improved such that, in the area outside their end portion, the plates on the reverse side are provided with a tongue on the upper or lower side, for example by a strip or lamella, to seal the joints and fasten to the supporting structure .

The proposed solution is suitable for use in building industry, especially for wood cladding and eventually from wood substitutes. It allows the creation of a relatively small weight tile that does not unduly burden the foundations and subsoil of the object or the object itself. The proposed cladding can be used on an object of any material, such as panel, masonry, old wood, etc. It allows the use of a thermal insulation layer such as polystyrene or mineral wool without unduly increasing the perimeter of the building, which is particularly important in the building opening areas like windows and doors. Due to its appearance, the cladding is almost indistinguishable from the “real wooden house” type with crossed beams. It can significantly improve the appearance of reconstructed buildings, masonry buildings, panel cells, stalls, etc., especially in mountainous areas, protected landscape areas and in buildings in the natural environment in general, such as recreational buildings near dams, golf courses, etc.

BRIEF DESCRIPTION OF THE DRAWINGS

The proposed solution is explained in more detail with the help of drawings, where Fig. 1 shows a detail of the corner end of one slab of the proposed building cladding, in a spatial view, Fig. 2 overall spatial view of the assembled cladding. Fig. 4 shows a detail of a top view of a corner joint of two plates according to the proposed solution and Fig. 5 shows a detail of a corner end of one plate showing angles, widths and lengths used in the terminology of this utility pattern to illustrate the proposed solution.

Example of technical solution

An exemplary embodiment of the proposed technical solution is the exterior cladding of buildings according to Figures 1 to 5.

A part of the exterior cladding of buildings, shown as a modular system for fastening around the walls of the building, is shown. The cladding may comprise conventional flat wood panels or substitutes thereof, mostly of rectangular shape, and further comprise flat wood panels 1 or substitutes thereof according to the proposed solution, intended to be placed at corner points of the building. The solution is designed for boards I which are intended to be placed around corners horizontally in their length direction. The parts of the panels 1 intended to be placed on the corners of the building already have a specific shape at the ends before the assembly of the assembly, allowing the corner ends of the panels 1 to form the corner edges of the finished lining in the assembled assembly. The design according to the proposed solution is as follows. The corner ends of the plates 1 are provided with a double-sided corner recess 2, which is realized over the entire thickness t of the plate I and thus defines the shape of the remaining narrower portion 3 of the plate 1. a part 4 which is fixedly fixed thereon, forming a projection 4 extending on the plate 1 at an angle and with respect to its back surface, where the face 5 of the projection 4 forms an extension of the end wall 6 of the plate I located on the narrower part 3 of the plate I. The projection 4 has a face 7 and sides 8 which fit into the recesses 2 of the corner ends of the other plates 1, with which the projection 4 forms a common corner edge in a composite system, for example at a corner of a building. In a composite modular system, after assembly of the lining, this corner edge consists of alternately stacked narrower parts 3 of the corner ends of the plates 1 located on one side of the building and the projections 4 of the corner ends of the plates 1 located on the adjacent side of the building.

In this exemplary embodiment, the projections 4 have a height equal to 3.2 times the plate thickness t, which is in the range of 1 to 15 times the plate thickness t expedient. The recess 2 on the ends of the corner plate and the cutout is designed as an acute angle, having an apex angle of 75 go ^D which is suitable in the range 50 to 90 °. This shape effectively prevents the spacing of the corners after assembly even after the material has shrunk due to shrinkage. The end walls 6 of the plate 1 in the recess 2, as well as the face 7 of the projection 4, are perpendicular to the longitudinal axis o of the plate. This accuracy allows the corner ends of all the plates to be identical, which greatly facilitates assembly. However, the angle between the face side of the plate 1 and the face 5 of the projection 4 may be different, for right-angled external corners of the building it will preferably be a right angle and for other external corners of a different angle it will preferably be the same angle as .

The recess 2 is the same on both sides of the corner end of the plate 1. The narrower portion 3 of each plate 1 extends symmetrically towards its end wall 6, and the projection 4 extends symmetrically towards its face 7. As shown in FIG. 1, the projection 4 is fixed to the plate 1 with its fiber direction in the same direction. such as the fiber direction of the plate 1 on which the projection 4 extends. It can also be seen in this figure that the projection 4 consists of two rigidly attached pieces 9, 10 of material, with the condition that their fiber direction is the same as the fiber direction of the plate 1. forms together with the plate 1 one body, is in the form of a fixed fixed, inseparable bead, and also and its pieces 9, 10 are in the form of bead.

The plate 1 is flat during its course and has the same thickness t throughout, throughout its section without the projection 4 the same as below the projection 4. The projection 4 also has the same thickness everywhere throughout its course, which is within the thickness range t of the plate 1. up to the length d of the narrower portion 3 of the plate 1. The plates 1 may have decorative and other conventional elements not specifically mentioned herein, such as beveled, rounded, or grooved edges in the length direction, decorating or grooving the surface, etc. grooves preventing torsion, etc., which are elements which are not related to the nature of the technical solution proposed here.

-3LZ, ZUU48 Ul

The proposed technical solution relates to the possibility of improving the strength of the formed corner joints by means of vertical joint pins JI. The joint of the corner ends of the boards 1 is preferably provided for at least one vertical joint pin JJL for particularly exposed joints.

In the area outside its end portion, each backsheet 1 is provided on the upper 5 side with a spring 12 in the form of a bar, allowing the joints to be sealed and invisible from the outside to be firmly fixed in place. The plates 1 are fixed as a conventional lining, preferably to a supporting structure, which may be formed, for example, by slats or prisms, or to the object to be lined.

Claims (12)

1. Exterior cladding of buildings, constructed as a modular system for fixing around walls 10 of a building, comprising flat panels (1) of wood or its substitutes with face and back faces, intended to be placed at least at corners of the building horizontally in their longitudinal direction, where it is at the ends of at least some of the plates (1) forming such that, in the assembled system, these corner ends of the plates (1) form corner edges of the finished lining, characterized in that the corner ends of the plates (1) ob15 extend a double-sided corner recess (2) over the entire thickness (r) the plate (1) and the remaining, narrower portion (3) of the plate (1) is provided on the reverse side of the plate (1) with an additional part which is fixedly fixed thereon forming a projection (4) extending on the plate (1) at a) with respect to its back surface, where the face (5) of the projection (4) forms an extension of the end wall (6) of the plate (1) and the projection (4) has a face (7) and flanks (8) which fit into the recesses (2) the corner ends of the other plates (1) with which they form this 20 a projection (4) in the state of a composite system with a common corner edge, wherein in the composite system this corner edge consists of alternately stacked narrower parts (3) of the corner ends of the plates (1) located on one side of the building and the projections (4) the ends of the plates (1) located on the adjacent side of the building. Exterior cladding of buildings according to claim 1, characterized in that the projection (4) 25 has a height (v) equal to 1 to 15 times the thickness (/) of the plate (1). Exterior cladding according to claims 1 and 2, characterized in that the recess (2) at the corner ends of the panel (1) has an apex angle (β) of 50 ° to 90 °, wherein the end walls (6) of the panel (1) the recess (2) as well as the nose (7) of the projection ( 4), are perpendicular to the longitudinal axis (o) of the plate (1). Exterior cladding of buildings according to claim 3, characterized in that the recess (2) on the two sides of the corner end of the panel (1) is the same. Exterior cladding of buildings according to claims 3 and 4, characterized in that the narrower part (3) of the panel (1) is directed towards its end wall (1). 6) widens symmetrically, and the projection (4) widens symmetrically towards its face (7). Exterior building cladding according to claims 1 to 5, characterized in that the projection (4) is fastened to the board (1) with its fiber direction the same as the fiber direction of the board (4) on which the projection (4) runs out. Exterior building cladding according to claim 6, characterized in that the projection (4) consists of at least two fixed pieces (9, 10) of material. 40 Exterior cladding of buildings according to claim 7, characterized in that the projection (4) is in the form of a plywood and pieces thereof ( 9,10) are also in the form of plywood. -49. Building exterior cladding according to claims 1 to 8, characterized in that the plate (1) has the same thickness (Z) everywhere, on its part without the projection (4) the same as under the projection (4). Exterior cladding of buildings according to claims 1 to 9, characterized in that the projection 5 (4) has the same thickness (z) throughout its course, and it is within the thickness (z) of the plate to the length (d) of the narrower portion (3) of the plate (1). Exterior cladding according to claims 1 to 10, characterized in that the corner end joints of the slabs (1) are provided with at least one vertical connecting pin (11). Exterior building cladding according to claims 1 to 11, characterized in that, in an area outside its end part, the backing plate (1) is provided on the upper or lower side with a tongue (12) for sealing the joints. and mounting in place.