PL70145Y1 - Construction element - Google Patents

Description

Pattern description

The subject of a utility model is a construction element.

Metal coated sandwich type building components are commonly used in the construction of walls and ceilings of buildings.

Building elements are known from the prior art, in which the sandwich structure is formed of surface plates and an insulating material sandwiched between them, such as mineral wool or foamed PUR / PIR / EPS insulation. In the prior art, the load bearing capacity of such building elements has been increased by profiling one or both of the surface plates as disclosed in, for example, WO 2007/144863, WO 03/078752 and PL 65533 Y1. Alternatively, the load-bearing capacity can be increased by placing the support frames inside the building element as disclosed in WO 2011/073535. Another way to increase the load-bearing capacity of the construction element is to increase the thickness of the surface plates.

The problem with the prior art solutions is that they are not suitable for producing bulky building elements that would be intended as such as a load-bearing ceiling, wall or floor element without external reinforcements or supporting frames inside the insulation layer or without the need for increasing the thickness of the surface plates. The mere provision of profiles to the surface plates is no longer sufficient to achieve the required load-bearing capacity of large-sized elements, and therefore large elements produced in this way do not allow sufficient spans to be obtained without a supporting structure. The problem of adding support frames or increasing the thickness of the surface plates is the heavy weight of the component, the increased manufacturing and material costs, and the constraints of the manufacturing process. In prior art building elements, the insulation layer, either polyurethane or polyisocyanate (PUR / PIR), is foamed between the surface plates, and the surface plates adhere to the insulation layer by bonding alone with adhesive. Thus, there is no composite effect formed between the surface plates and the insulation layer, but the surface plates and the insulation layer act as separate structures held together by the adhesive of the insulation layer. This does not provide the building element with properties that would allow it to be used as a large element without separate supporting structures.

The above problems do not occur with medium-sized elements, but arise in the production of large-sized elements without separate supporting grids. Due to the above-described prior art solutions, they remain disadvantageous in the production of large-sized elements designed to achieve as large spans as possible and long-term strength under varying loads.

Therefore, the purpose of a utility model is to provide a building element which is suitable for the construction of ceilings, floors and walls and allows the above-mentioned problems to be solved.

A building element according to a utility model in the shape of a cuboid having two opposite face walls formed by the first surface plate and the second surface plate and an insulation layer interposed therebetween, the first surface plate and the second surface plate being attached to the insulation layer, and having sidewalls comprising stepped projections and depressions, each sidewall being complementary to an opposite sidewall, characterized in that the first surface plate and the second surface plate are composite panels each having longitudinal folds, the longitudinal folds the fold is grooved and includes a bottom and two reinforcement ribs connected to the bottom, and reinforcement ribs connect the bottom to the composite panel, the bottom surface comprising surface profiles in the form of transverse folds at a constant distance from each other and relative to the longitudinal direction of the longitudinal fold, and furthermore the longitudinal folds extend from the composite panel towards the inside of the insulation layer.

Preferably, the insulating material of the insulating layer is polyurethane (PUR) or polyisocyanate (PIR).

Preferably, the reinforcing rib and the underside of the longitudinal folds are joined by the side folds, the side folds being formed so as to project relative to the side rib, and furthermore transverse folds are provided on the side folds which are transverse to the longitudinal direction of the longitudinal fold and extend over the longitudinal fold. them.

The advantage of the utility model is a significant improvement in the load-bearing capacity of the construction element when both surface plates are composite plates, in which the composite effect in connection with the insulation is advantageously taken into account by various profiles made on the plate in the form of longitudinal, transverse and lateral bends. The shapes of the bends in the composite board are optimized to be favorable for the composite effect while allowing insulation extrusion (PUR / PIR) and the composite board to form a composite structure. The composite board has three shapes that prevent the insulation from moving or slipping relative to the composite board. In a composite construction, the surface plate and the extruded insulation form a building element that is capable of bearing much greater loads than prior art building elements. This allows for greater spans in ceiling and floor structures, which in turn reduces the number of supporting structures, speeds up the construction process and provides better long-term strength under varying loads.

The object of the utility model is shown in the attached drawing, in which fig. 1 is a partial view of a composite board used in a building element according to a utility model, fig. 2 - a view of a building element according to a utility model in which two composite panels from fig. 1 are used.

1 shows a composite panel 12 used in a building element 1 according to a utility model. The composite panel 12 includes folds made to achieve a composite effect between the composite panel 12 and the insulation layer 4. The composite effect shapes prevent the insulation layer 4 and the composite panel 12 from moving in three directions relative to each other. Advantageously, the shapes producing the composite effect prevent the insulating layer 4 and the composite panel 12 from moving or slipping in three directions relative to each other. The longitudinal folds 5 prevent the insulation layer 4 and the composite panel 12 from moving in the transverse direction, i.e. the direction transverse to the longitudinal fold 5. The longitudinal folds 5 are grooved and comprise a bottom 6 and at least one stiffening rib 8 connected to the bottom, the The stiffening rib 8 in turn connects the underside 6 with the composite panel 12. Preferably, at least one surface of the longitudinal folds 5 of the utility model that rests against the insulation layer 4 has surface profiles made as transverse folds 7 at a constant distance from each other and transversely to each other. in the longitudinal direction of the longitudinal fold 5, to prevent the composite panel 12 from moving in the longitudinal direction relative to the longitudinal fold 5. The bottom 6 of the longitudinal folds 5 is preferably profiled with transverse folds 7 at a constant distance from each other to prevent the composite panel 12 and the insulation layer 4 from sliding or slipping. in the longitudinal direction or I'm myself. The longitudinal folds 5 of the utility model extend from the composite panel 12 towards the inside of the insulating layer 4 (W2> W1), and the stiffening rib 8 and the bottom 6 of the longitudinal folds 5 are preferably joined by side folds 9, the side folds 9 being so formed, that they project relative to the stiffening rib 8 and thus prevent the composite panel 12 and the insulation layer 4 from sliding or sliding relative to each other in the vertical direction. The transverse folds 7, which are transverse to the longitudinal folds 5, preferably rest on and extend over the side folds 9. As a result of the longitudinal, transverse and side bends 5, 7, 9, a strong composite effect is obtained in the building element to ensure a uniform structure between the composite board 12 and the insulating layer 4. The composite effect allows the use of large-sized building elements 1 in structures with large spans that can range from 6 to 8 meters. At such spans and under high loads, the composite effect is of great importance in the building element 1, the composite effect significantly increasing the buckling strength of the surface plate. The size of the building element 1 according to the utility model, without supporting structures, may be of the order of 6 to 8 χ from 2 to 4 m.

Fig. 2 shows a construction element having a general cuboid shape with end walls formed by first and second surface plates (2, 3) and side walls 13 having stepped projections and depressions. Each of the side walls 13 is complementarily shaped with respect to the opposite side wall 13. The first surface plate 2 and the second surface plate 3 are composite panels 12 of the construction described with reference to Fig. 1. The material used in the insulating layer 4 is preferably polyurethane. (PUR) or polyisocyanurate (PIR).

When the building element 1 is used for an outer wall or roof structure, the heat recovery or heat distribution pipes can be installed in the building element 1 during manufacture. In the vicinity of the insulation layer 4, close to the inner surface plate, there may also be integrated heat distribution tubing with fluid circulating inside to bring heat to the interior of the building. When the building element 1 is used in a floor structure, the pipes for underfloor heating may be installed on the surface of the element before the surface of the building element is poured with cement or other plate coating.

Claims (3)

Protective reservations 1. A cuboid-shaped building element (1) having two opposite face walls formed by the first surface plate (2) and a second surface plate (3) and an insulating layer (4) interposed therebetween, the first surface plate (2) ) and the second surface plate (3) are attached to the insulating layer (4), and having side walls (13) having stepped projections and depressions, each side wall (13) being complementarily formed with respect to the side wall (13) opposite thereto. ), characterized in that the first surface plate (2) and the second surface plate (3) are composite panels (12), each of which comprises longitudinal folds (5), the longitudinal fold (5) being grooved and comprising a bottom (6). ) and two reinforcement ribs (8) connected to the bottom, and reinforcement ribs (8) connect the bottom (6) to the composite panel (12), the bottom surface (6) having surface profiles in the form of transverse bends (7) arranged at a constant distance from each other and transversely to the longitudinal direction of the longitudinal fold (5), and furthermore the longitudinal folds (5) extend from the composite board (12) towards the inside of the insulating layer (4) (W2> W1). 2. Construction element according to claim The method of claim 1, characterized in that the insulating material of the insulating layer (4) is polyurethane (PUR) or polyisocyanurate (PIR). Construction element according to claim A device according to claim 1, characterized in that the reinforcing rib (8) and the underside (6) of the longitudinal folds (5) are joined by side folds (9), the side folds (9) being formed so as to protrude relative to the side rib (8). and moreover, transverse folds (7) are disposed at the side bends (9) which are transverse to the longitudinal direction of the longitudinal fold (5) and extend over them.