DE102005047478A1 - Roofing system for halls, has two layers provided with two profile units that are supported on supporting surfaces of supports in sections, respectively, where supports are screwed or welded with each other - Google Patents

Abstract

The system has a substructure with two supports (1, 5), where the support (5) encloses an angle with the support (1) in a top view. The supports (1, 5) exhibit supporting surfaces (2, 6) that are arranged in such a manner that their heights are adjustable. Two layers (3, 7) are provided with two profile units (4, 8) that are supported on the supporting surfaces in sections, respectively. The supports are supported on top of each other, where the supports are screwed or welded with each other. The profile units are made of polymer material or metallic material.

Description

The The present invention relates to a roofing system, in particular for covering halls, comprising a substructure with at least a first carrier, having at least a first bearing surface, and a first layer with at least one profile element, at least in sections on the first contact surface supported.

Such a roofing system with trapezoidal sheet profile elements is for example from the German patent application DE 29 02 231 A1 known. In this case, a layer of trapezoidal sheet metal profiles bears on the supports supporting them in the same direction, in such a way that the longitudinal orientation of the trapezoidal sheet metal sections runs at a right angle to the orientation of the carrier. Against the background of a desirable cost-effective, weight-saving and resource-saving construction, the above-described roofing system - and in particular the support substructure - can not meet the demands of modern buildings in all respects satisfying.

task The invention is therefore a roofing system of the above so that in weight and thus in the costs and resources of the support substructure Savings are possible.

These The object is achieved by a roofing system of the type mentioned, in which the Substructure has at least a second carrier, which in a plan view with the first carrier includes an angle, and the second carrier at least a second bearing surface has, wherein the first and the second support surface offset in height are arranged, and that the roofing system continues to be a second layer having at least one profile element, which is at least partially supported on the second bearing surface and himself first bearer and second carrier support each other.

by virtue of The two layers of profile elements can be inside the roof shell When recording vertical loads, a biaxial load transfer takes place. This takes over each one position of profile elements the uniaxial load transfer along the longitudinal direction the profile elements. Taking up vertical loads - e.g. at Snow load - the upper, second position of the profile elements takes place a removal of Load in the longitudinal direction the profile elements. It comes to a deflection of these profile elements in the area between two supporting ones second carriers, wherein in this area the second layer of profile elements of the underlying first layer of profile elements is supported. Within the first layer of profile elements is now in turn the uniaxial load transfer in the longitudinal direction of the profile elements. By the uniaxial removal of load of each of the two layers can be the Carrier substructure clear weight-saving dimensioned than with uniaxial load transfer in the simultaneous presence of only one group of parallel carriers and only one layer of rectified profile elements. In addition, can due to the removal of load of each of the two layers of profile elements and thus the distribution of the load on the two Laying the stress of individual layers can be reduced. Thereby will it be possible to increase the distance between two adjacent supporting beams, which also contributes to weight savings in the carrier substructure.

Next the above described recording of vertical loads, the individual layers also horizontal loads - for example, wind forces - record and in the area forward, so as to act as a thrust field. So that can Profile element layers assume the function of a diagonal bracing of the carrier substructure. In particular, resulting from the inventive arrangement two on top of each other arranged profiled element layers two superimposed shear fields for two different directions, causing a higher disc effect of the whole Roof shell is achievable. This allows the saving of roofing, what in turn to a further weight saving in terms of Support substructure contributes.

Advantageous may be that at least two first carrier are provided and the Profile element of the first layer from one of the first carrier to a other of the first carriers extends. This arrangement causes increased stability of the roofing system.

Advantageous may also be that at least two second carrier are provided and the profile element the second layer extends from one of the second carriers to another of the second Carrier extends. This also increases the stability of the roofing system.

It may be advantageous that the second carrier connected to the first carriers are. This results in a particularly rigid support substructure with increased stability, which supports the load transfer in two directions.

From Advantage may also be that the first and the second carrier with each other are welded. This results in a very stable Connection between the carriers, the more even Power flow allowed.

It can be cheap prove that the first and the second carrier screwed together are. This type of connection offers mounting advantages at a comparatively low cost.

It can be as cheap as well prove that the first carrier and the second carrier at least partially interpenetrate each other. This arrangement provides the carrier Advantages regarding a more even one Force flow, and results in addition a very stable and rigid carrier substructure.

It may prove to be advantageous that the first carrier and the second carrier have a right angle to each other in a plan view. By This arrangement results in a support grid, in which the removal the load within the carrier substructure in two perpendicular directions, which is for many stress cases expected to be similar Stress in the mutually perpendicular directions Cheap is.

moreover it may prove advantageous if the first and the second carrier have a different cross-sectional geometry. hereby can be an advantage in terms of easier connection between the two groups of carriers.

In addition, can it cheap be the first carrier and the second carriers Wide flange beams are. These carriers are readily available in a variety of dimensions and especially for Roof structures suitable.

Furthermore it can be cheap be the first carrier and the second carriers have different cross-sectional dimensions. This is it is possible every group of porters to adapt specifically to the occurring loads against the background a desired weight savings.

As well It may be advantageous that the first carrier have a higher load capacity than the second Carrier. This is also about the adaptation of the respective group of carriers to the occurring loads and a corresponding weight saving.

moreover It may be beneficial if the distance between the first and the second bearing surface essentially the height of the profile element corresponds. This will make it possible for the top edge of the Profile element and the upper edge of the second carrier are approximately at the same height, so that the profile element also without load contact contact the second carriers and the profile elements of the first layer may have.

Advantageous may further be that the profile element is a longitudinally having extending uniform cross-sectional geometry. This results a uniform deformation the profile element along its longitudinal orientation.

It can be cheap prove that the profile element is a longitudinally extending unitary Meander-shaped cross-sectional geometry having. Due to this cross-sectional geometry results in a very homogeneous stress profile along the cross-sectional profile.

moreover It can be cheap prove when the profile element is a longitudinally extending uniform trapezoidal Has cross-sectional geometry. This cross-sectional geometry offers at low weight increased Rigidity of the profile element along its longitudinal orientation.

Farther It can be cheap prove that the profile element made of a metallic material consists. Profile elements from this group of materials are themselves at low wall thicknesses very stable, can high forces record and are about it also temperature / weather resistant.

Farther It may prove advantageous if the profile element made a polymeric material. Profile elements from this group of Materials offer advantages in terms of weight savings.

It may be advantageous that the longitudinal alignment of the profile elements the first layer in a different direction than the longitudinal orientation of those supporting first carrier. This allows better utilization of the higher rigidity of the profile elements in longitudinal direction respectively.

In addition, can it may be beneficial that the longitudinal orientation the profile elements of the first layer with the longitudinal orientation of these supporting first carrier includes a right angle. This can be the higher Stiffness of the profile elements in the longitudinal direction optimally utilized become.

In addition, it may be advantageous that the longitudinal alignment of the profile elements of the second layer in a different direction than the Längsaus direction of these supporting second carriers. This allows a better utilization of the higher stiffness of the profile elements in longitudinal alignment.

From Advantage may still be that the longitudinal alignment of the profile elements the second layer with the longitudinal orientation of those supporting second carrier includes a right angle. This can be the higher Stiffness of the profile elements in the longitudinal direction optimally utilized become.

Advantageous may be that the longitudinal orientation the profile elements of the first layer in a different direction as the longitudinal orientation the profile elements of the second layer. By this kind of arrangement Is it possible, occurring forces within the roof shell in two different directions ablate, where the forces split up to the individual layers.

It can be cheap be that the longitudinal alignment the profile elements of the first layer with the longitudinal orientation of the profile elements the second layer encloses a right angle. This arrangement of the layers the profile elements is suitable for most use cases, where with an approximately same Load calculated in the mutually perpendicular directions can be.

As well it can be cheap be that the second layer of the profile elements at least partially supported on the first layer of the profile elements. This will be the load-bearing first layer supported by the second layer, whereby the occurring Transfer load to both layers becomes.

From Advantage may be that the first and / or the second layer several Having side-by-side profile elements. This allows the Cover also very big Roof areas at Profile elements that are only available with a limited width.

As well It may be advantageous that the first and / or the second layer having a plurality of profile elements arranged one behind the other. This also allows the large-area coverage of roofs for profile elements that are only available with a limited length.

there It can be cheap prove that the profile elements of the first layer and / or The second layer at least partially overlap longitudinally and / or transversely. This arrangement allows the transmission of forces from one profile element to the adjacent profile element. simultaneously elevated through the overlap the rigidity and stability of the Profile elements in this area. In addition, results from this Arrangement of a tight roof shell.

Farther may be advantageous that at least one profile element of the first Location with the first carriers is connected and / or at least one profile element of the second layer connected to the second carriers is. Increased by this connection the rigidity and stability of the entire roofing.

there It can be cheap prove that the profile element welded to the straps or is glued. These types of connections allow a reliable and durable connection between profile elements and girders even force flow.

there It can also be as cheap prove that the profile element with the straps over fasteners like For example, set bolts, rivets or tapping screws connected is. The use of said fasteners results in extremely stable and also easy to make connections.

moreover it can be cheap be that the first layer and the second layer of the profile elements connected to each other. This results in a stiffener and stability increase of clam-shell roofing.

there It may be advantageous that the two layers glued together or welded. Such compounds are durable and offer the advantage of a uniform power flow.

there It may also be advantageous that the two layers have fasteners such as setting bolts, rivets or tapping screws with each other are connected. These connections are relatively easy to realize, which are very stable and reliable at the same time.

It may be advantageous that the first layer and the second layer of the Profile elements with each other and at least the profile elements of first position with the first carriers or the profile elements of the second layer connected to the second carriers are. This will increase the stiffening and stability of the entire roof structure reached.

Furthermore, it may be advantageous that at least one functional layer, for example a sliding or insulating layer, is arranged between the first layer and the second layer of the profile elements. A sliding layer, for example, ensures that the noise is reduced or even avoided in expanding / contracting and mutually shifting layers of profile elements, while by a Dämm layer, the temperatures within the building, which is covered by the roof construction, are favorably influenced.

In addition, can It may be advantageous that on the second layer of the profile elements at least one vapor barrier layer and / or an insulating layer and / or a roof sealing layer is arranged. An insulating layer positively influences the temperatures within the building, which covered by the roof construction, while a vapor barrier layer ensures that moisture inside the building does not prevent any existing insulation layer reached. A roofing layer protects the entire roof structure from moisture or moisture.

It demonstrate:

1 a spatial representation of an inventive roofing system with a support grid forming substructure and two layers of profile elements whose longitudinal orientations are perpendicular to each other

2 a side view of a roof covering system according to the invention with mutually perpendicular first and second carriers and two layers of profile elements whose longitudinal orientations are perpendicular to each other, and arranged on the second layer of profile elements functional layers

1 shows the spatial representation of a roofing system according to the invention. This includes first carriers ( 1 ) and second supports ( 5 ), which form a right angle in plan view. The included angle can also deviate from 90 °. The first and second beams, which have a Breitflanschgeometrie are connected at the intersection points by welding together and penetrate each other. Other types of connection or connection of the first and two carriers are conceivable. First ( 2 ) and second ( 6 ) Bearing surfaces of the first and second carrier are arranged offset in height to each other.

On the first bearing surfaces of the first carrier is a first layer ( 3 ) of profile elements ( 4 ), in such a way that the longitudinal alignment of the profile elements is perpendicular to the longitudinal direction of the first carrier. On the second bearing surfaces of the second carrier is a second layer ( 7 ) of profile elements ( 8th ), wherein the longitudinal alignment of the profile elements is perpendicular to the longitudinal direction of the second carrier. This results in an arrangement of the profile elements of the first and second layer, wherein the longitudinal orientation of the profile elements of the first layer with the longitudinal orientation of the profile elements of the second layer encloses a right angle. Other included angles are possible.

Of the height offset between the first and second bearing surface is such that the Top edge of the first layer of profile elements with the top edge the second carrier at substantially the same level is. As a result, the profile elements of the second layer are at least in sections on the profile elements of the first layer. As well is a deviating height offset possible. The profile elements of the first and second layer have a longitudinal extending uniform trapezoidal cross-sectional geometry on.

The mode of action and mode of operation of the invention will be explained in more detail below:
The roof covering system according to the invention is used in particular for covering halls. Above all, in large halls, it is important here to save weight, which at the same time a cost and resource savings is connected. Weight savings is possible primarily in the support structure to support the roof structure. The inventive arrangement of longitudinal profile elements in conjunction with a suitable and adapted support substructure a significant weight savings is possible.

there become two layers of longitudinal profile elements used on top of each other are arranged, with the longitudinal alignment the profile elements of the first layer with the longitudinal orientation of the profile elements the second layer includes an angle. At the same time a Support substructure used to account for the described arrangement of the profile elements wearing. These are first carriers present, on the first bearing surfaces, the profile elements support the first layer, and second carriers, on the second bearing surfaces the profile elements of the second layer are supported. The second carriers are supported here on the first carriers from. In addition, in an advantageous embodiment, the arrangement the first and the second carrier such that the first and second bearing surfaces one height offset have, whereby the upper edge of resting on the first bearing surface Profile elements of the first layer with the upper edge of the second carrier essentially the same height lies.

Due to the arrangement of the two layers of profile elements within the roof shell, a biaxial load transfer can take place. In each case a layer of profile elements takes over the uniaxial load transfer along the longitudinal direction of the profile elements. When loading the upper, second layer of Profile elements, for example, by a snow load, there is a removal of the load in the longitudinal direction of the profile elements. The deflection of these profile elements in the area between two supporting second carriers is counteracted by the underlying profile elements of the first layer. This is possible due to the above described adjusted height offset of the first and second carriers. Within the first layer of profile elements, the uniaxial load transfer takes place in the longitudinal direction of the profile elements.

By the uniaxial removal of load of each of the two layers can be the Support substructure significantly weight-saving dimensioned than uniaxial Load transfer with simultaneous presence of only one group of parallel carriers and only one layer of rectified profile elements. In addition, can due to the removal of load of each of the two layers of profile elements and thus the distribution of the load on the two Laying the stress of individual layers can be reduced. Thereby will it be possible to increase the distance between two adjacent supporting beams, which also contributes to weight savings in the carrier substructure. In addition, can by dividing the registered roof load on the two profile element layers the length the individual profile elements of each layer are chosen to be larger than single-leaf profile element roof construction with only transverse to the longitudinal direction the profile elements extending first carriers.

In 2 a second embodiment of the invention is shown. To avoid repetition, only the differences from the first embodiment will be discussed.

Unlike the in 1 illustrated first embodiment, the second embodiment according to 2 one on the upper second layer 7 of profile elements 8th several additional functional layers 9 . 10 and 11 on. The functional layer following the second layer of profile elements 9 is a vapor barrier layer, which is intended to prevent rising from the inside of the building, which is covered by the roof construction described, rising water vapor to the thermal barrier coating 10 arrives. In contrast, the insulating layer has 10 the function of positively influencing the temperature within the building. This means, for example, that the insulating layer should prevent heat generated inside the building from being easily released to the outside environment via the roof. The roofing layer 11 again has the task to protect the insulating layer from environmental influences or to seal the entire roof structure against moisture or moisture.

Claims (37)

Roof covering system, in particular for covering halls, comprising a substructure with at least one first support ( 1 ), the at least one first contact surface ( 2 ), and a first layer ( 3 ) with at least one profile element ( 4 ), which is supported at least in sections on the first support surface, characterized in that the substructure at least one second support ( 5 ), which in a plan view with the first carrier ( 1 ) includes an angle, and the second support ( 5 ) at least one second contact surface ( 6 ), the first ( 2 ) and the second bearing surface ( 6 ) are offset in height, and that the roofing system continues to have a second layer ( 7 ) with at least one profile element ( 8th ), which at least partially on the second bearing surface ( 6 ), and first carrier ( 1 ) and second carrier ( 5 ) abut each other. Roofing system according to claim 1, characterized in that at least two first supports ( 1 ) are provided and the profile element ( 4 ) of the first layer ( 3 ) from one of the first carriers ( 1 ) to another of the first carriers ( 1 ). Roofing system according to claim 1 or 2, characterized in that at least two second supports ( 5 ) are provided and the profile element ( 8th ) of the second layer ( 7 ) from one of the second carriers ( 5 ) to another of the second carriers ( 5 ). Roofing system according to at least one of the preceding Claims, characterized in that the second carriers are connected to the first carriers are. Roofing system according to claim 4, characterized in that that the first and the second carrier are welded together. Roofing system according to claim 4, characterized in that that the first and the second carrier screwed together are. Roofing system according to at least one of the preceding Claims, characterized in that the first carrier and the second carrier at least partially interpenetrate each other. Roofing system according to at least one of the preceding Claims, characterized in that the first carriers and the second carriers are in one Top view at right angles to each other. Roofing system according to at least one of the preceding Claims, characterized in that the first and the second carrier a have different cross-sectional geometry. Roofing system according to at least one of the preceding Claims, characterized in that the first carriers and the second carriers are wide flange carriers. Roofing system according to at least one of the preceding Claims, characterized in that the first carriers and the second carriers are different Have cross-sectional dimensions. Roofing system according to at least one of the preceding Claims, characterized in that the first carriers have a higher load capacity than the second Carrier. Roofing system according to at least one of the preceding Claims, characterized in that the distance between the first and the second bearing surface essentially the height of the profile element corresponds. Roofing system according to at least one of the preceding Claims, characterized in that the profile element is a longitudinally having extending uniform cross-sectional geometry. Roofing system according to at least one of the preceding Claims, characterized in that the profile element is a longitudinally extending uniform meandering cross-sectional geometry having. Roofing system according to at least one of the preceding Claims, characterized in that the profile element is a longitudinally extending uniform trapezoidal cross-sectional geometry having. Roofing system according to at least one of the preceding Claims, characterized in that the profile element of a metallic Material exists. Roofing system according to at least one of the preceding Claims, characterized in that the profile element of a polymeric Material exists. Roofing system according to at least one of the preceding Claims, characterized in that the longitudinal orientation of the profile elements the first layer in a different direction than the longitudinal orientation of those supporting first carrier. Roofing system according to at least one of the preceding Claims, characterized in that the longitudinal orientation of the profile elements the first layer with the longitudinal orientation of this supportive first carrier includes a right angle. Roofing system according to at least one of the preceding Claims, characterized in that the longitudinal orientation of the profile elements the second layer in a different direction than the longitudinal orientation of those supporting second carrier. Roofing system according to at least one of the preceding Claims, characterized in that the longitudinal orientation of the profile elements the second layer with the longitudinal orientation of this supportive second carrier includes a right angle. Roofing system according to at least one of the preceding Claims, characterized in that the longitudinal orientation of the profile elements the first layer in a different direction than the longitudinal orientation the profile elements of the second layer. Roofing system according to at least one of the preceding Claims, characterized in that the longitudinal orientation of the profile elements the first layer with the longitudinal orientation of Profile elements of the second layer encloses a right angle. Roofing system according to at least one of the preceding Claims, characterized in that the second layer of the profile elements at least in sections on the first layer of the profile elements supported. Roofing system according to at least one of the preceding Claims, characterized in that the first and / or the second layer has several juxtaposed profile elements. Roofing system according to at least one of the preceding Claims, characterized in that the first and / or the second layer having a plurality of profile elements arranged one behind the other. Roofing system according to claim 26 or 27, characterized in that the profile elements of the first layer and / or the second layer at least partially along and / or across overlap. Roofing system according to at least one of the preceding Claims, characterized in that at least one profile element of the first La ge with the first carriers is connected and / or at least one profile element of the second layer with the second carriers connected is. Roofing system according to claim 29, characterized in that the profile element is welded or welded to the carriers is glued. Roofing system according to claim 29, characterized characterized in that the profile element with the carriers via connecting elements such as set bolts, rivets or tapping screws connected is. Roofing system according to at least one of the preceding Claims, characterized in that the first layer and the second layer the profile elements is interconnected. Roofing system according to claim 32, characterized in that the two layers are glued together or welded are. Roofing system according to claim 32, characterized characterized in that the two layers over fasteners such as For example, setting bolts, rivets or tapping screws connected together are. Roofing system according to at least one of the preceding Claims, characterized in that the first layer and the second layer the profile elements together and at least the profile elements the first layer with the first carriers or the profile elements the second layer are connected to the second carriers. Roofing system according to at least one of the preceding Claims, characterized in that between the first layer and the second Location of the profile elements at least one functional layer, for example a sliding or insulating layer, is arranged. Roofing system according to at least one of the preceding claims, characterized in that on the second layer of the profile elements at least one vapor barrier layer ( 9 ) and / or an insulating layer ( 10 ) and / or a roofing layer ( 11 ) is arranged.