DE4418890A1 - Substructure for double-skin roof systems - Google Patents

Abstract

A heat insulating layer (20) is mounted on a support structure (10). This is fitted with spacer sections (22) which are formed by an oblong U-profile (22). The profile web (24) forms the fastening surface (24) for fixing a cover (44). Its arms (26,28), which are shorter than the thickness of the heat insulating layer, extend at right angles to the web into the insulating layer. The web (24) and support structure (10) are connected together by bolt-shaped connectors (30) set spaced out from each other. The connectors can be threaded screws (30) whose shaft passes through the web, insulating layer and support structure. The support structure can be formed by a trapezoidal plate (10). <IMAGE>

Description

The invention relates to a substructure for two shelled roof systems, with a supporting structure, one on the Support structure arranged thermal insulation layer and distance profiles that are connected to the support structure and on a flat fastening on the side facing away from the supporting structure have surface for fastening a covering, wherein the mounting surface abge on the support structure facing surface of the thermal barrier coating.

They are substructures for double-skin roofs known in which continuous elongated Z-profiles Sheet or bracket used as spacer profiles the. The Z-profiles or brackets are parallel in the Ab was attached to each other on a trapezoidal sheet that one leg on the flat raised beads of the trapezoidal sheet lies on. Between the Z-profiles or brackets and the trapezoidal sheet is provided with a vapor barrier. On finally insulation material is placed between two neighboring bearded Z-profiles or holding bracket inserted. After application an upper trapezoidal sheet is attached the upper legs of the Z-profile or bracket consolidates.  

When using the well-known Z-profile or bracket only relatively soft thermal insulation layers can be used because the thermal insulation layers are between two Adjacent Z profiles or brackets are introduced have to. Because of this relatively soft thermal insulation layer the known substructure is not tread-resistant, so there is a risk that the below the heat Insulation layer provided vapor barrier when installing the Substructure and when installing the covering is stepped through. The soft thermal barrier coating can moreover not for a lateral support of the Z-profile or bracket, so that the danger be stands that the Z-profile or the bracket deformed improper load. In addition, in Connection area between the thermal insulation layer and the Bridge of the Z-profile or the retaining bracket missing parts occur because there is a risk of damage during the assembly process Displacement of the thermal insulation layer can come.

Another major disadvantage of the known sub construction is that by the web of the Z-profile or the bracket a continuous Ver bond between the upper and lower trapezoidal sheet is formed along the entire length of the Z-profile or the bracket through the thermal insulation layer passes through and forms a cold bridge that is too heavy weighing condensate problems.

Finally, the known Z-profiles and retaining bracket the distance between the two legs sets so that a Z-profile or bracket only for a certain thickness of thermal insulation can be used can.

The invention has for its object with constructive simple means a quick and easy to assemble Substructure for double-skin roof systems through which excellent thermal insulation is guaranteed.

Starting from the generic state of the art this object achieved in that the Distance profiles formed by an elongated U-profile be, the web forms the mounting surface and its legs, the length of which is less than the thickness the thermal insulation layer, essentially perpendicular to extend the web into the thermal insulation layer. The jetty and the support structure are by spaced bolts shaped connecting elements connected together.

The connecting elements are preferably threaded screws ben, for example tapping screws with countersunk head, Shaft through the web, the thermal insulation and the support shell goes through.

In a preferred embodiment of the substructure the supporting structure is made of a trapezoidal sheet with flat Beading and beading formed, the verb are connected to the flat raised beads.

There is none in the substructure according to the invention Thermal bridge between the web of the U-profile and the lower support structure. The thermal insulation layer is only from the Fasteners penetrated. Consequently, none occur Condensation problems.

In addition, the subcon structure the use occurs solid continuous fiber  insulation boards, so that the risk of penetration of the Vapor barrier is prevented. The substructure is after placing the fiber insulation panels, the preferred wise have a bulk density of 120 kg / m³, walkable, see above that simple assembly is possible.

Another advantage is that a tread-resistant Thermal insulation layer can be laid pressed, so that there are no imperfections in the thermal insulation layer. This ensures optimal thermal insulation.

Through the use of solid thermal insulation layers in addition, the horizontal distance between the distance profiles be chosen relatively large from each other, so that with little Effort a relatively quick assembly of the substructure tion is possible.

The distance profiles according to the invention can also be used also for thermal insulation layers of different thickness be used. The only requirement is that the Leg of the U-profiles shorter than the thickness of the heat insulation layers are formed so that no cold bridge becomes.

After all, the substructure can be used by almost everyone Covers, such as B. a brick covering, a Trapezoidal sheet roofing, a sheet metal roof, an indu thatched roof or a corrugated roof covering used become.

An embodiment of the invention is shown below explained in more detail with reference to drawings. It shows:  

Figure 1 is a perspective sectional view of a two-shell roof system.

Fig. 2 is a cross-sectional view of a double-skin roof system.

1 and 2 Dachsy systems shown in FIGS . 1 and 2 each have a lower trapezoidal sheet 10 with horizontal flat raised beads 12 and deep beads 14 and an upper trapezoidal sheet 44 with raised beads 46 and deep beads 48 as the upper shell. The Dachsy systems of Fig. 1 and Fig. 2 differ only in that the beads of the lower trapezoidal sheet 10 and the upper trapezoidal sheet 44 in the roof system shown in Fig. 1 in the same direction and in the roof system shown in Fig. 2 perpendicular to each other.

A vapor barrier 18 is arranged on the top of the lower trapezoidal sheet 10 and rests on the raised beads 12 . On the vapor barrier 18 a continuous fiber insulation plate 20 is placed, which preferably has a bulk density of 120 kg / m³.

On the top of the fiber insulation panel 20 , a plurality of U-profiles 22 made of galvanized steel sheet are arranged in parallel at a distance from one another. The U-profiles 22 rest with their web 24 on the top of the fiber insulation panel 20 . The legs 26 and 28 extending essentially perpendicular to the web 24 are pressed into the fiber insulation panel 20 in such a way that they are firmly surrounded by the material of the fiber insulation panel 20 . The length of the legs 26 , 28 is substantially less than the thickness of the fiber insulation board 20 . The length is chosen so that a relative displacement between the fiber insulation panel 20 and U-profile 22 is prevented.

The U-profile 22 is connected to the raised beads 12 of the lower trapezoidal sheet 10 by means of a plurality of self-tapping screws 30 arranged in the longitudinal direction of the U-profile 22 (only one is shown in FIG. 2). The Blechschrau ben 30 have at their upper end a countersunk head 32 which rests in a countersunk opening in the middle of the web 24 of the U-profile 22 . The lower, threaded end of the self-tapping screw 30 is screwed into the respective raised bead 12 .

A sarking membrane 42 is arranged on the substructure formed by the lower trapezoidal sheet 10 , the vapor barrier 18 , the fiber insulation panel 20 and the U-profile 22 . The upper trapezoidal sheet 44 is placed on the underlay 42 so that its beads 46 , 48 run perpendicular to the U-profiles 22 . The upper trapezoidal sheet 44 is screwed by means of sheet metal screws 50 in the area of its deep beads 48 to the web 24 of the respective U-profile 22 arranged underneath.

Claims (4)

1. Substructure for double-skin roof systems, with a support structure ( 10 ), a heat insulation layer ( 20 ) arranged on the support structure ( 10 ) and spacer profiles ( 22 ) which are connected to the support structure ( 10 ) and on which the support structure ( 10 ) is turned away Side have a flat fastening surface ( 24 ) for fastening a covering ( 44 ), the fastening surface ( 24 ) resting on the surface of the thermal insulation layer ( 20 ) facing away from the supporting structure ( 10 ), characterized in that

• - That the spacer profiles are formed by an elongated U-profile ( 22 ), the web ( 24 ) of which forms the fastening surface and whose legs ( 26 , 28 ), whose length is less than the thickness of the heat insulation layer ( 20 ), in substantially perpendicular to the web ( 24 ) in the thermal barrier layer ( 20 ), and
• - That the web ( 24 ) and the support structure ( 10 ) are connected by spaced bolt-shaped Ver connecting elements ( 30 ).

2. Substructure according to claim 1, characterized in that the connecting elements are threaded screws ( 30 ), the shaft of which goes through the web ( 24 ), the thermal insulation ( 20 ) and the support structure ( 10 ). 3. Substructure according to claim 1 or 2, characterized in that the supporting structure of a trapezoidal sheet ( 10 ) with flat deep beads ( 14 ) and raised beads ( 12 ) is formed, and that the connecting elements ( 30 ) with the flat raised beads ( 12 ) are connected. 4. Substructure according to one of the preceding claims, characterized in that the thermal insulation layer is a non-slip fiber insulation panel ( 20 ).