RU141043U1 - BUILDING ELEMENT - Google Patents

Abstract

1. A building element (1) comprising a first surface sheet (2), a second surface sheet (3) and an insulating layer (4) located between them, the first surface sheet (2) and the second surface sheet (3) attached to this insulating layer (4), characterized in that at least one of these surface sheets (2, 3) is a component sheet (12) and has shapes that provide a component effect between this component sheet (12) and the insulating layer (4) and prevent the displacement of the insulating layer (4) in three directions announcements regarding this component sheet (12) .2. A building element (1) according to claim 1, characterized in that the insulating material used in the insulating layer (4) is polyurethane (PUR) or polyisocyanurate (PIR). 3. A building element (1) according to claim 1, characterized in that the component sheet (12) contains longitudinal folds (5), preventing the component sheet (12) from shifting in the direction transverse to the fold (5). A building element (1) according to claim 3, characterized in that at least one surface of the longitudinal folds (5) located opposite the insulating layer (4) is provided with a surface profile in the form of transverse folds (7) passing at a fixed distance from other and perpendicular to the longitudinal direction of the longitudinal fold (5), to prevent the component sheet (12) from shifting in the longitudinal direction relative to the longitudinal fold (5) .5. The building element (1) according to claim 3, characterized in that the longitudinal seam (5) is grooved and contains a base (6) and at least one wall (8) connected to this base, the wall (8) connecting

Description

Technical field

[0001] This utility model relates to the building element described in paragraph 1 of the attached formula. This element contains a first surface sheet, a second surface sheet and an insulating layer located between them, to which said first and second surface sheets are adhered.

State of the art

[0002] Wall and ceiling structures of buildings typically use metal-coated sandwich type building elements.

[0003] Building elements are known in the art in which a multilayer structure is formed of surface sheets and an insulating material located between them, such as mineral wool or foam insulation polyurethane / polyisocyanurate / polystyrene foam. The bearing capacity of such known building elements has been increased by profiling one or both surface sheets, as disclosed, for example, in WO 2007/144863. In addition, the bearing capacity can be increased by placing support frames inside the building element, as disclosed in WO 2011/073535. Another way to increase the bearing capacity of a building element is to increase the thickness of the surface sheets.

[0004] Meanwhile, these known solutions have a significant disadvantage in that they are not suitable for the manufacture of a large building element that could be used as a supporting element for a ceiling, wall or floor without using external reinforcement or support frames inside the insulating layer, or without increasing the thickness of the surface sheets. Moreover, the profiling of surface sheets in itself is not sufficient to achieve the required bearing capacity of large elements, and for this reason, large elements manufactured by this method do not allow for a sufficient span length without the use of supporting structures. However, when the support frames are included in the design or the thickness of the surface sheets increases, another problem arises, consisting in increasing the weight of the building element, increasing production and material costs, as well as increasing the limitations caused by the production process.

[0005] According to the prior art, the insulating layer (polyurethane / polyisocyanurate) of the building element is foamed between the surface sheets, and the surface sheets adhere to the insulation layer only by adhesion adhesion. Therefore, there is no component effect created between the surface sheets and the insulating layer, and the surface sheets and the insulating layer function as separate structures held together due to the adhesion of the insulating layer. This circumstance does not allow to obtain a building element with the desired characteristics, which can be used as a large element without separate supporting structures.

[0006] The above problems are not inherent in medium sized elements — they occur when large sized elements are produced without separate support meshes. For this reason, solutions of the prior art are unsuitable for the production of large elements designed to obtain as long spans as possible and to provide long-term strength under the influence of various loads.

Utility Model Essence

[0007] In view of the foregoing, the objective of this utility model is to develop a building element suitable for creating building structures of the ceiling, floor and walls and allowing to remove the aforementioned problems of the prior art. The problem is solved by developing a building element, characterized by the features of the distinctive part of claim 1 of the attached formula. In particular, this building element is characterized in that at least one of the surface sheets is a component sheet and has shapes that create a component effect between the component sheet and the insulation layer and prevent the insulation layer from shifting in three directions relative to the component sheet.

[0008] Preferred embodiments of the utility model are disclosed in the dependent claims.

[0009] The idea of this utility model is that the load-bearing capacity of a building element is significantly increased if at least one of these surface sheets is a component sheet that provides an arrangement effect with insulation, preferably due to different sheet profiles made in the form of longitudinal , transverse and side folds. According to a first preferred embodiment of the utility model, one of the surface sheets is made of a carrier grooved sheet or a flat sheet. According to a second preferred embodiment, both surface sheets are said component sheet. The shapes of the folds of the component sheet are optimized to achieve the benefits of the component effect, as a result of which it becomes possible to obtain insulation (polyurethane / polyisocyanurate) by extrusion and use the component sheet to form the assembled structure. The component sheet has three shapes that prevent the insulation from slipping or sliding relative to the component sheet. In the assembled structure, the surface sheet and extruded insulation form a building element capable of withstanding significantly higher loads than the building elements of the prior art. This allows for long spans in ceiling and floor structures, which, in turn, reduces the number of supporting structures, speeds up the construction process and ensures durability despite the effect of various loads.

Brief description of figures and item numbers

[0010] Next, a utility model is disclosed by the example of its preferred options described with reference to the accompanying drawings, moreover:

figure 1 shows a partial view of the component sheet used in the proposed building element;

figure 2 shows a partial view of the proposed building element;

figure 3 shows a second variant of the proposed building element.

Item Numbers

1 - building element

2 - first surface sheet

3 - second surface sheet

4 - insulating layer

5 - longitudinal fold

6 - base

7 - transverse fold

8 - wall

9 - side fold

10 - heat recovery pipe

11 - heat distribution pipe

12 - component sheet

Utility Model Disclosure

[0011] Fig. 1 shows a component sheet 12 used in a preferred embodiment of the proposed building element 1. The component sheet 12 is provided with folds formed to achieve a component effect between the component sheet 12 and the insulating layer 4. The sheet shapes providing the component effect prevent the displacement of the insulating layer 4 and the component sheet 12 in three directions relative to each other. Preferably, the shapes providing the component effect prevent the displacement or sliding of the insulating layer 4 and the component sheet 12 in three directions relative to each other. The longitudinal folds 5 prevent the insulating layer 4 and the component sheet 12 from shifting in the transverse direction relative to each other, that is, in the transverse direction relative to the longitudinal fold 5. The longitudinal folds 5 are grooved and comprise a base 6 and at least one wall 8 connected to the base. The wall 8, in turn, interconnects the base 6 and the component sheet 12. According to a preferred embodiment, at least one surface of the longitudinal folds 5, located opposite the insulating layer 4, has surface profiles made in the form of a transverse fold 7 at a fixed distance from each other and perpendicular to the longitudinal direction of the longitudinal fold 5. They are designed to prevent displacement of the component sheet 12 in the longitudinal direction relative to the longitudinal fold 5. Bases e 6 of the longitudinal folds 5 is preferably profiled with transverse folds 7 arranged at a fixed distance from each other and used to prevent the component sheet 12 and the insulating layer 4 from moving or sliding in the longitudinal direction relative to each other. According to a preferred embodiment of the utility model, the longitudinal folds 5 extend from the component sheet 12 towards the insulating layer 4 (W2> W1), and the wall 8 and the base 6 of the longitudinal folds 5 are preferably connected by side folds 9, which are formed so that they protrude relatively walls 8. These circumstances prevent displacement or sliding of the component sheet 12 and the insulating layer 4 in the vertical direction relative to each other. The folds (7), perpendicular to the longitudinal folds 5, preferably abut against the side folds 9 and extend over them.

[0012] These longitudinal, transverse and side folds 5, 7, 9 cause a pronounced component effect for the building element, as a result of which they provide a single structure between the component sheet 12 and the insulating layer 4. This component effect allows the use of building elements 1 of large sizes in structures with a longer span, which can be on the order of 6 to 8 m. With such span lengths and at high loads, the component effect is of great importance in building element 1. It is significant increases the stability limit of the buckling of the surface sheet. The dimensions of the proposed building element 1 without supporting structures can be of the order of 6-8 × 2-4 m.

[0013] Figure 2 shows a first preferred embodiment of the proposed building element 1. In this embodiment, the first surface sheet 2 is a component sheet 12, and the second surface sheet 3 is a carrier groove sheet. The carrier grooved sheet also has a profile that increases its rigidity. However, it differs from the component sheet 12 in that it does not have shapes providing a component effect. Therefore, the carrier grooved sheet reinforces the building element 1 only due to its own rigidity, but not as a single structure with the insulating layer. The material used for the insulating layer 4, preferably polyurethane (PUR) or polyisocyanurate (PIR).

[0014] If the building element 1 is used in the construction of external walls or roofs, pipes for utilization or distribution of heat may be installed in the building element 1 during its production. Figure 2 shows a heat recovery pipe 10 embedded in the insulating layer 4 near the outer surface sheet. The fluid circulating in this pipeline will absorb heat from the air. Near the insulating layer 4, next to the inner surface sheet, there is a built-in heat distribution pipe 11 in which a fluid circulates to transfer heat into the building. If the building element 1 is used in the floor structure, a pipeline for heating the floor can be installed on the surface of this element, it is installed before pouring concrete or other coatings onto the indicated surface of the building element.

[0015] FIG. 3 shows a second preferred embodiment of a building element 1, in which both surface sheets are a collection of component sheet 12.

[0016] It will be apparent to those skilled in the art that, due to the development of the technique, the basic idea of the present utility model can be implemented in many different ways. Therefore, the present utility model and the options for its implementation should not be limited to the examples described above, but may vary within the scope of the claims defined by the attached formula.

Claims (9)

1. A building element (1) comprising a first surface sheet (2), a second surface sheet (3) and an insulating layer (4) located between them, the first surface sheet (2) and the second surface sheet (3) attached to this insulating layer (4), characterized in that at least one of these surface sheets (2, 3) is a component sheet (12) and has shapes that provide a component effect between this component sheet (12) and the insulating layer (4) and prevent the displacement of the insulating layer (4) in three directions announcements regarding this component sheet (12). 2. The building element (1) according to claim 1, characterized in that the insulating material used in the insulating layer (4) is polyurethane (PUR) or polyisocyanurate (PIR). 3. The building element (1) according to claim 1, characterized in that the component sheet (12) contains longitudinal folds (5), preventing the displacement of the component sheet (12) in the direction transverse to the fold (5). 4. The building element (1) according to claim 3, characterized in that at least one surface of the longitudinal folds (5), located opposite the insulating layer (4), is provided with a surface profile in the form of transverse folds (7), passing at a fixed distance from each other and perpendicular to the longitudinal direction of the longitudinal fold (5), to prevent displacement of the component sheet (12) in the longitudinal direction relative to the longitudinal fold (5). 5. The building element (1) according to claim 3, characterized in that the longitudinal fold (5) is grooved and contains a base (6) and at least one wall (8) connected to this base, and the wall (8) connects base (6) with component sheet (12). 6. The building element (1) according to claim 3, characterized in that the longitudinal folds (5) expand in the direction from the component sheet (12) into the insulating layer (4) (W2> W1) and prevent the component sheet (12) from shifting to longitudinally and in height with respect to the flange (5). 7. The building element (1) according to claim 5, characterized in that the wall (8) and the base (6) of the longitudinal folds (5) are connected by side folds (9), which are made in such a way that they protrude relative to the wall (8), while the transverse folds (7), perpendicular to the longitudinal direction of the longitudinal fold (5), abut against the specified side folds (9) and pass on top of them. 8. The building element (1) according to claim 1, characterized in that in the insulating layer (4), near the outer surface sheet, a heat recovery pipe (10) is integrated, and the fluid circulating in this pipe is designed to absorb heat from the atmospheric air. 9. The building element (1) according to claim 1, characterized in that near the insulating layer (4), next to the inner surface sheet, a built-in heat distribution pipe (11) is provided in which a fluid circulates, providing heat transfer inside the building.

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