DE9410680U1 - Substructure for attaching ventilated facades - Google Patents

Description

Substructure for the installation of ventilated facades

The innovation concerns a substructure for the installation of ventilated facades.

Since the 1950s, it has been common practice to provide larger buildings with a ventilated facade, for example made of natural stone. This makes it possible to build cost-effective buildings from reinforced concrete elements and to give them the desired appearance by subsequently covering them with a curtain wall. These facades allow the generous installation of insulating material behind the curtain wall elements and also enable a building, especially older buildings, to be given an exterior that meets the respective requirements by installing a new or modified facade.

Typically, the curtain wall elements are individually fixed to the building’s masonry or concrete using supporting and retaining anchors.

This usual method of installation has a number of disadvantages. The installation of individual elements requires at least four wall anchors per element and therefore a large number of drill holes in the building. Installing the elements on a substructure made of steel profiles, e.g. behind each panel joint to save drill holes, only slightly reduces the number of holes required. In order not to endanger the structural stability of a building, it is not possible to install drill holes in the substructure of a building at any point or in any number of places.

The known substructures also have the disadvantage that they bulk up slightly between their fastening points when thermally expanding, which leads to problematic loading at the fastening points of the support anchors on the facade elements.

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In recent years there has been an increased need to equip old buildings with new facades. The fact that the facade panels are no longer stable enough for today's standards can often only be solved by demolishing the cladding panels. This allows the insulation behind the facade to be adapted to the latest thermal conditions. In addition, the buildings can be given an exterior that meets today's requirements.

After the old facade has been removed, however, considerable renovation work is often required to ensure the structural stability of the building, as a large number of new drill holes are required for the new facade or the old anchors must be removed from the walls and the holes that have been created must be refilled. The problems that arise often result in renovation costs that are so high that renovation does not seem worthwhile. In old buildings, non-load-bearing infills have often been made for parapets and window pillars that cannot bear any load.

The aim of this innovation was therefore to develop a substructure for attaching ventilated facade elements that requires the smallest number of drill holes for attaching wall or concrete anchors in order to affect the statics of a building as little as possible. In addition, the wall or concrete anchors should not be subject to alternating transverse loads due to thermal expansion of the substructure and the load-bearing anchor fastening points on the facade elements should be subjected to as little load as possible. Furthermore, the facade elements should be able to be attached in as many different ways as possible, i.e. not exclusively vertically, in order to allow as much freedom as possible for the design options when designing the facade.

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The innovative solution to this problem results in two different cases, which can be provided with a fundamentally identical substructure.

For wall sections with windows lying one above the other, usually called parapet fields, a substructure for attaching ventilated facades is presented, which consists of vertically attachable substructure profiles, retaining anchors and retaining means for attaching facade elements to the substructure profile and is characterized in that the length of a profile section corresponds approximately to the distance from the top to the bottom edge of two windows lying one above the other and each section can be attached to a retaining anchor approximately in its middle third and retaining means for attaching facade elements can be attached to the profile section.

Since the profile is only attached at a single point, this can be chosen so that it is located in a floor ceiling, a ring beam or on a support of a steel skeleton structure, which is always located between two windows on two floors above each other. The profile is relatively short and preferably has a U-shaped cross-section. Fasteners for attaching facade elements can be attached to it. For example, T- or Y-shaped holders can also be attached here, which enable facade elements to be attached at an angle of between about 20 and 70° to the vertical. For example, the sill and soffit panel can be attached at an angle and the design options when designing the facade are considerably greater than with the conventional attachment of facade elements.

For the cladding of continuous vertical walls, a substructure for the attachment of ventilated facades is proposed, which consists of vertically attachable substructure profiles, retaining anchors and retaining means for attaching facade elements to the substructure profile and is characterized in that the

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The length of a profile section corresponds to at least one storey height and each section can be attached to a retaining anchor at one end, can be fastened vertically at its other end and retaining means for attaching facade elements can be attached to the profile section.

These profile sections can be selected so that they run over one or more floors and can be attached at their lower end, for example to the profile that follows below. The attachment must be done in such a way that the profile can move vertically here. This means that the weight of the facade is only taken up by the retaining anchors attached at the top in the floor ceiling, the ring beam or the support of a steel skeleton construction and the lower attachment points act as sliding bearings and leave enough room for the usual thermal expansion of the profile construction. Since these profiles are only subjected to tensile stress downwards, an L-shaped profile cross-section is preferred because, in contrast to the U-profile described above, a weight saving can be achieved and the stability is completely sufficient for the tensile load. U-profiles can also be used for greater loads.

The construction can also be mounted the other way around, i.e. fixed at the bottom and vertically movable at the top.

The substructure profiles for attaching the facade elements are preferably made of stainless steel or aluminum. The plate anchors used as holding devices for the facade elements and the holding anchors for the profiles are preferably made of stainless steel.

The invention is explained in more detail below with reference to the figures:

Fig. 1 shows a section of a building wall with windows and a ventilated facade in vertical section.

Fig. 2 shows a substructure profile according to the invention with lower sliding bearing and wall anchor in a side view.

Fig. 3 shows the installation of a substructure profile in a floor slab as in Fig. 2 in horizontal section.

Fig. 4 shows a substructure profile according to the invention as in Fig.

2 and 3 with facade elements attached in horizontal section.

In Fig. 1, a wall section with a floor slab 1 can be seen between two windows 2 lying one above the other. The wall section between the windows is clad with ventilated facade elements 3, 4, 5. The facade elements are attached with retaining means 6, 7, 8 to a vertically running, U-shaped substructure profile 9, which is attached with a single wall or concrete anchor 10 in the floor slab or a ring beam 1. Facade elements such as parapet bands 4 are attached with conventional retaining means 7, which are welded to the substructure profile 9. In order to make it possible to attach facade elements at an angle to the vertical, Y-shaped retaining means 6 or T-shaped retaining means 8 are also provided, which are also welded to the substructure profile and allow the facade elements 3, 5 to be attached at an angle.

On vertically continuous wall sections such as window sills or support pillars, the facade elements are preferably attached to a substructure as shown in Fig. 2. The wall or concrete anchors 10 are in turn attached to the floor slabs or ring beams. The lower profile 9a is attached to the wall anchor 10 in its upper area. The profile is preferably L-shaped and has a welded-on tab 11 at its upper end, to which the profile 9b, which in turn is attached to a wall anchor at its upper end in a

floor ceiling or a ring beam. The screw connection is made at a vertical slot 12 in the bracket 11, so that the screw connection acts like a sliding bearing that can only move vertically in order to allow the thermal expansion of the upper profile 9b without exposing the anchors to alternating transverse loads.

Fig. 3 shows in horizontal section how the retaining anchors 10 are attached to the floor slab or ring beam 1. The L-profiles 9 are attached to them, for example welded.

The vertical facade elements 4, 4a are then attached to the profile 9 using the plate anchors 7, as can be seen in Fig. 4. The facade elements 4a shown in the picture are used to cover window frames.

Claims (10)

Expectations 1. Substructure for attaching ventilated facades, consisting of vertically attachable substructure profiles (9), retaining anchors (10) and holding means (6,7,8) for attaching facade elements (3,4,5) to the substructure profile (9), characterized in that the length of a profile section corresponds approximately to the distance from the top to the bottom edge of two windows (2) lying one above the other and each section can be attached to a retaining anchor (10) approximately in its middle third and holding means (6,7,8) for attaching facade elements can be fastened to the profile section. 2. Substructure for attaching ventilated facades, consisting of vertically attachable substructure profiles (9), retaining anchors (10) and holding means (7) for attaching facade elements (4) to the substructure profile (9), characterized in that the length of a profile section corresponds to at least one storey height and each section can be attached to a retaining anchor (10) at one end, can be fastened vertically at its other end and holding means (7) for attaching facade elements (4) can be fastened to the profile section (9). 3. Substructure according to claim 2, characterized in that the vertically movable fastening is a vertically extending slot (12) acting as a sliding bearing. 4. Substructure according to claim 2 or 3, characterized in that the profile (9a) is connected to the rigidly fixed end via a fastening -2- possibility (11) for the vertically movable fastening (12) of the connecting profile (9b). 5. Substructure according to claims 1 to 4, characterized in that the profile (9) has an L-shaped cross section. 6. Substructure according to claims 1 to 4, characterized in that the profile (9) has a U-shaped cross section. 7. Substructure according to claims 1 to 6, characterized in that the holding means (6) for attaching facade elements (3) at an angle between 20 and 70° to the vertical are Y-shaped. 8. Substructure according to claims 1 to 6, characterized in that the holding means (8) for attaching facade elements (5) at an angle between 20 and 70° to the vertical are T-shaped. 9. Substructure according to claims 1 to 8, characterized in that the profile (9) consists of stainless steel or aluminum. 10. Substructure according to claims 1 to 9, characterized in that the holding means (6,7,8) and holding anchors (10) consist of stainless steel.