NL2005931C2 - ROOF ELEMENT. - Google Patents

Description

Roof element

The invention relates to a roof element, to be placed as a whole element between the bearing construction or bearing walls of the roof, of the type hanging, the roof element comprising inter alia: - Longitudinal profiles, which with open side can be directed both inwards and outwards relative to the roof element itself; - head profiles, which are encirclingly connected to the longitudinal profiles; - suspension profiles which are connected to the head profiles such that the reaction forces 10 are transferred to each other as a tensile and shear load due to the inherent weight of the element, including the loads acting thereon; - support profiles; which are connected to the longitudinal profiles and head profiles - panel-filling cladding, which is arranged in the form of a trapezoidal steel plate between the upper flange and lower flange of the longitudinal beams or end beams on the supporting profiles intended for this purpose; - coupling plates which are applied to the longitudinal profiles of two contiguous roof elements such that the stability forces between the roof elements are mutually transmitted, whereby the required disk action is provided in connection with the required stability provision of a building; - insulation material which is connected to the panel-filling sheeting by means of an adhesive connection or by mechanical fastening means, wherein a sealing strip of flexible material is arranged between adjoining longitudinal profiles of roof elements.

The invention is based on the state of the art as disclosed by the international patent application WO 85/03540 with the roof element further developed thereon as disclosed by the international patent application WO 98/28504. The last-mentioned patent application has been improved at the state of the art and is registered under patent application NL 1020359. The roof element known from the aforementioned patents comprises a rectangular open frame of steel longitudinal and transverse profiles fixed to each other. This framework is covered at the top with a flat cover plate and at the bottom a bottom plate spans between the longitudinal and transverse profiles such that the longitudinal and transverse profiles protrude below the bottom plate. An insulation blanket is located loosely within the framework and rests on the bottom plate with the intervention of a vapor-proof layer, for example a PVC film. Both cross sections are C-shaped. The longitudinal profile is Z-shaped on one side while on the other side it is designed as an inverted L-shaped profile. The flanges on the top of both the transverse and longitudinal profiles point to the frame side. Parallel to the longitudinal profiles on the upper side of the frame, with mutual distance 2 between the transverse profiles, reinforcing ribs giving the transverse profiles extra stability. The bottom plate also forms the ceiling side and consists of a loose corrugated steel flange on the lower flanges of the transverse profiles directed towards the frame side. The cover plate is a rectangular OSB plate with dimensions that correspond to those of the frame and rests on the stiffening ribs and upper flanges of the longitudinal and transverse profiles and is fixed to those flanges with rivets all around. The cover plate is slightly offset with respect to the frame, so that it protrudes along one transverse profile and the inverted L-shaped longitudinal profile and lies back to approximately the same extent along the other transverse profile and the Z-shaped longitudinal profile. Roofing is applied on top of the cover plate.

A roof element according to the known technique has several disadvantages, namely: - the use of a resting steel corrugated sheet with solely the function as a ceiling plate and support for the insulation blanket; - the linear thermal bridge of the longitudinal and transverse profiles due to the absence of an insulation material in this zone; - the limitation of the bearing capacity of the entire element due to the possibility of local folding of the bearing profiles on the bearing structure; - the relatively high costs for applying stiffening ribs, with the many and expensive finishing operations and cover plates; - the sensitivity to capacity reduction of the element as a disk construction as a result of the influence of moisture in the cover plate due to condensation during inaccurate execution of assembly work; - the scaffolding works required during assembly in order to work safely.

The object of the invention is to remedy at least the aforementioned disadvantages. To this end trapezoidal steel plates have been used which function as a support for the walkable insulation, as a tilting support for the main girders and as a stabilizing disk for the stability provision of a part or whole of the structure. Due to the structural application of the trapezoidal steel plates, reinforcement ribs and cover plates have become superfluous. Due to the positioning of the stabilizing disc on the underside of the frame, at least below the insulating layer, and the material specifications of this stabilizing disc, no capacity reduction of the disc construction is possible due to moisture. By mounting the support profiles, which are mounted in the form of angular steel on the inside of the frame on both the longitudinal and the end profiles, at a desired height on the profile body, any desired insulation thickness can be applied in such a way that the insulation at least a specified thickness within the framework of the roof element protrudes above the surrounding longitudinal and head profiles. By adding (during the mounting of the roof elements) a narrow strip of insulation with the specified thickness on the longitudinal and head profiles, a linear thermal bridge is prevented. By applying a 3 L-shaped profile, coupled to the end beams, a suspension of the roof elements has been created that is insensitive to body folds. As a result, the suspension can always be weighted to any desired weight, independently of the main beams. By using the roof elements between the bearing structure or bearing walls, a working height has been created which is almost equal to the standing height of the fitter. Provisions on the roof elements make it possible to use fall protection immediately, making other scaffolding in or around the building superfluous with regard to the installation of the roof elements.

The roof element according to the present invention has the property of being designed with two longitudinal beams with profile dimensions that are in accordance with the desired span and load. The load on the roof element is immediately borne by the insulation on the trapezoidal steel plates, so that an evenly distributed line load on the side members is effective. By the way of connecting the trapezoidal steel plates to the main beams, the main beams are laterally stabilized. This is in contrast to a roof element according to the known technique in which the two main beams are point-loaded by reinforcement ribs and the corrugated steel plate only has a visual function. A substantial reduction in materials and labor is also achieved through the structural application of the trapezoidal steel plates. By using trapezoidal steel plates which are coupled on four sides of the rectangular frame to the longitudinal or end girders, on the underside of the frame (that is, under the insulating layer), the material specifications (that is, galvanized steel plates) prevent this. that condensation forms against the sheeting and / or decay of structural capacity of the roof element or component can occur. By this method of assembling and positioning the stabilizing component, a higher degree of structural integrity is achieved with respect to the roof element according to known technology. With the addition of an L-shaped profile to the head profiles, a mounting possibility is created whereby the transverse forces occurring at the location of the support are transmitted by shear forces and not by axial forces in the web plates of the profiles as in the known art. Through this method of load transfer, a higher capacity with regard to transverse force transfer is created, a simpler way of mounting is created and a good transfer of the stability forces from the disk elements to the substructure is created.

In this embodiment, a multiple coupling is preferably arranged between two roof elements in the longitudinal direction on top of the longitudinal profiles (that is outside of the roof element), such that a complete stability element is created over the entire roof surface. This is in contrast to the known technique in which the cover plates serve for the transmission of the horizontal forces, as a result of which a labor-intensive coupling of elements is to be realized which must be realized in the work and only limited adjustment space is possible. In addition, an integrated hoisting device is preferably included in this embodiment which also functions as a point of contact for possible fall protection. By adding the aforementioned facilities, work can be carried out easily, quickly and safely, without further requirements with regard to scaffolding work. Also, in this embodiment use is preferably made of a glue connection between the insulation and the trapezoidal steel plates, in those cases where no vapor-proofing layer is required, and a rivet connection or connection with self-drilling screws, between the, usually galvanized, steel parts.

In the following the invention is further elucidated with reference to examples shown in the drawings. Hereby shows: - FIG. 1 is a perspective view of an exploded roof element according to the present invention; FIG. 2 shows a detail of the view according to the viewing direction indicated by arrow A in fig. 1 in the mounted state in the case of a supporting wall; 15 - FIG. 3 shows a detail of the view according to the viewing direction indicated by arrow A in fig. 1 in the mounted state in the case of a steel supporting structure; FIG. 4 shows a detail of the view according to arrow B indicated in FIG. 1 in mounted condition in the case of connection of two adjacent roof elements, wherein the longitudinal profiles with open side are directed towards the roof element; 20 - FIG. 5 shows a detail of the view according to arrow B indicated in FIG. 1 in mounted condition in the case of connection of two adjacent roof elements, wherein the longitudinal profiles are directed away from the roof element with the open side open.

In the figures reference is made to the same part with the same reference number.

The roof element according to the present invention shown in fig. 1 comprises: longitudinal profiles designed as C-profile (1); girders designed as U-profile (2); suspension profiles designed as an L-profile (3) for suspension on a load-bearing structure (19) or load-bearing wall (18); support profile designed as an L-profile (4) for the support and connection of the trapezoidal steel plates (5); form-retaining insulating material shaped as a sheet (6) in combination with formable insulating strips (8) in the longitudinal and head profiles; shape-retaining insulating material on the longitudinal and head profiles shaped as a sheet (7); coupling plates (10) designed as square or rectangular; connecting means (11) designed as a hole-filling or self-drilling device; lifting device (12) designed as an eye or loop, which also acts as fall protection; sealing strip (13) shaped as a strip; connecting means (14) designed as self-drilling; clamping plate (15) designed as a plate for coupling to a swiveling anchor (17) in combination with rivets (16); roof covering (9) designed as a seal in combination with strips of roof covering for the purpose of sealing the connecting roof elements (20).

The C-profiles (1) are connected (11) to the U-profiles (2) in such a way that they together with the trapezoidal steel plates (5), which are laid and connected with self-drilling connecting means (14) on the four sides used support profiles (4), 5 forms a stable, strong and rigid roof element, which can achieve a span of at least 15 meters and, possibly together with the other roof elements, provides the stability provision in the area concerned. Through the structural application of the trapezoidal steel plates, a support is created for the longitudinal profiles (1) that prevents tilting instability. This is in contrast to the known technique where the corrugated steel plates have no structural function. Given trapezoidal steel plates (5) in the present invention have the function of load transfer to the longitudinal profiles (1) as well as the function of ceiling plate. The head profiles (2) in the form of U-profiles are of such a size that they enclose the C-profiles, whereby a simple connection (11) between the profiles is possible. Due to the correct positioning of the holes, the connecting means 15 (11) in the head profiles (2) can be used for both the coupling of the suspension profile (3) and the support profile (4). This saves labor and material.

The insulating plates (6) in the present invention come to rest on the trapezoidal steel plates. A uniformly distributed load is hereby exerted on the side members (1). The insulation boards can be used with any desired thickness, depending on the desired insulation properties. The insulation boards must protrude within the framework of the longitudinal (1) and head profiles (2) at least a specified thickness above the longitudinal and head profiles, such that the edge insulation (7), which is applied in the work, with the top side at the same level as the insulation boards (6) within the framework. By using the insulating plates (6) as the outer material, internal condensation is prevented and the structural integrity of the bearing and stability construction is guaranteed. By applying edge insulation (7) in combination with filling insulation (8) a continuous cold bridge is prevented. This is in contrast to the known technique in which the steel profiles are not covered with an insulating material, so that the use of a good air seal between two roof panels that close to one another is essential and as such gives a sensitive point of implementation. The insulation boards (6) are preferably designed in a form-retaining version in order to be able to guarantee any walkability of the roof. The insulation plates are also preferably designed with a higher lambda value such that a thicker insulation package is obtained, whereby the trapezoidal steel plates are connected to the web of the profiles as close as possible to the lower flange of the side members (1) in order to achieve optimum chicken support. Said insulation plates should preferably be glued to the trapezoidal steel plates and preferably to the web plates of the longitudinal profiles if use is made of the embodiment according to Fig. 5. If a vapor-repellent layer must be used between the insulation and the trapezoidal steel plates , mechanical fasteners are required. The use of the filling insulation (8) prevents the insulation plates (6) from being slid into the longitudinal (1) and end profiles (2) or having to be rejuvenated (in the embodiment according to Fig. 4), which is not easy from the point of view of implementation. and / or impossible. If the longitudinal profiles are positioned with the open side facing away from the roof element (embodiment according to Fig. 5), the filling insulation (8) can be designed with such a width that it protrudes at least half the space between two adjacent roof elements outside the longitudinal profiles so that when mounted of the roof elements a complete closure, optionally in combination with a compand, of the adjusting space is created (embodiment according to fig. 5).

The coupling plates (10) are mounted in the present invention on the upper flanges of the longitudinal profiles (1), such that the connecting means (16) can be placed in a simple manner from the top of the roof element. Relevant connecting means are preferably rivets, so that a high mounting speed can be achieved. This is in contrast to the known technique where, when coupling the elements, many connecting means are needed in the cover plates. By applying the correct combination of coupling plates, connecting means and their correct number, an almost completely deformation-free coupling is created between two adjacent roof elements. By using coupling plates (10), it is possible to create an adjustment space between roof elements that can be wholly or partially discounted in the work, or should be, with any dimensional deviations of the bearing structure. The remaining adjusting space between the elements is automatically sealed by the optionally projecting fill insulation (8) (in an embodiment according to Fig. 5) in combination with a self-adhesive or glued sealing material (13), for example in the form of compriband.

The roof elements according to the present invention can be applied to a supporting structure or a supporting wall. In both cases the elements are anchored to the underlying supporting structure such that the tensile loads due to wind suction and the shear loads due to the horizontal loads can be absorbed. For this purpose, when applying the roof elements to a supporting structure, use is made of nail nails (16) or self-drilling screws in the underlying supporting structure. When applying roof elements to a supporting wall, use is made of a clamping plate (15) in combination with a wind-up anchor (17), which is already included in the supporting wall during the preparatory work.

During the mounting of the roof elements of the present invention any laying direction can in principle be adhered to. This is in contrast to the known technique in which a mandatory laying direction must be adhered to in connection with 7 overhanging parts that are also susceptible to damage during transport and assembly. This flexibility in laying direction has advantages with regard to the logistics aspects to and on the construction site. The use of the integrated hoisting devices (12), which can also be easily removed as required, makes it possible to work with fall protection. Work is carried out in this manner without the immediate need for additional scaffolding. The coupling plates (10), wind-up anchorage (15, 17) and edge insulation (7) are applied during or after the roof elements have been laid, after which the last strip of roof covering (20) (which may also consist of rubber or plastic) is applied. Preferably, the roof covering (9) is already applied to the insulation (6) during prefabrication, including the overlapping lengths of the roof covering (20), whereby in the open-air storage of roof elements is also prevented.

Other embodiments of the invention are also conceivable, for example the use of other (metal) material, such as aluminum, or other shapes, such as Sigma-shaped profiles instead of C-shaped profiles. The open side of the longitudinal profiles can be directed both to the inside of the roof element and to the outside of the roof element. Instead of rivets, rivets and self-drilling screws, a different bonding or connecting means may be used, of mechanical type, such as bolts, nuts and staples, but also glue. Combinations of various such means are also conceivable. The trapezoidal steel plates can be replaced by other plate systems, for example sandwich panels, or be connected in another way to the longitudinal profiles, for example knocked-out lips from the longitudinal profiles. The roof element can be of a different design than rectangular, for example polygonal. The mounting profile can be replaced by another profile shape, for example a Z-shaped profile. The roof element should preferably be dimensionally stable and be sufficiently fixed on the substrate to be able to transfer the forces acting on the roof element to the substructure.

Claims (8)

1. Roof element with longitudinal profiles (1) and head profiles (2), characterized in that a positioning system (5) is located at a desirable height relative to the lower flange of the longitudinal profiles, which is connected to the longitudinal and head profiles ( 1, 2, 4), wherein the orientation of the open side of the longitudinal profiles can be directed both inwards and outwards with respect to the roof element itself, that in combination with couplings (10) to adjacent roof element (s) and connection (15, 16, 17) provides a supporting structure with a substantial part of the stability provision for the structure; the roof element 10 is preferably, at least substantially, flat. Roof element according to claim 1, characterized in that the roof element hangs on the lower supporting structure with the aid of a profile detailed as a suspension profile (3), which profile can also be designed as a head profile (2) with the integrated function of a suspension profile (3), and is connected to this lower support structure by means of fixing means (15, 16, 17). 3. Roof element as claimed in claim 1 or 2, characterized in that the roof element is preferably, at least substantially, provided with a form-retaining insulating material which, possibly with the intervention of a vapor-barrier layer, is connected to the underlying plate system, either by an adhesive connection or by a mechanical connection; the roof element is preferably provided with formable insulation in the longitudinal and head profiles; the roof element is preferably provided with form-retaining insulation above the longitudinal and head profiles. Roof element as claimed in any of the foregoing claims, characterized in that the roof element is preferably provided with integrated hoisting provisions which preferably function as fall protection; the roof element is preferably provided in a prefabricated phase with a roof covering, rubber or plastic which is preferably designed with an excess length for sealing between two adjacent roof elements and also prevents watering in during storage in the open air. 5. Roof element as claimed in any of the foregoing claims, characterized in that the fixing means (11, 14, 16) comprise hole-filling, self-drilling or bolts in combination with associated nuts and rings. Roof element according to one of the preceding claims, characterized in that the sealing strip comprises flexible material. Roof element according to one of the preceding claims, characterized in that the roof element comprises cold-rolled or set profiles. 8. Roof element with at least one measure according to the preceding descriptions and / or drawings.