DE202023107061U1 - Height-adjustable heavy-duty angle system - Google Patents

Abstract

Height-adjustable heavy-duty angle system comprising a wall rail (10) with a central, longitudinally aligned adjustment bar (12), and a mounting bracket (13) with support, characterized in that
- the mounting bracket (13) is configured such that it can be moved continuously on the wall rail (10) and can be mounted in a removable manner
- and that the heavy load angle system is designed and constructed to carry heavy loads of 200 - 800 kg, preferably 300 - 600 kg, particularly preferably 350 - 370 kg.

Description

The present invention relates to a height-adjustable heavy-duty angle system made of galvanized steel. The heavy-duty angle consists of a wall rail and a mounting bracket. The wall rail has a centrally arranged longitudinal adjustment bar that allows for continuous adjustment. To ensure maximum stability, the wall rail is also connected to the mounting bracket.

Background and state of the art

The preferred height-adjustable heavy-duty angle system is intended for the assembly of suspended, insulated timber frame walls for energy-saving renovations. It is a continuously adjustable angle for attaching facades and wall elements in serial building renovations. These systems offer a reliable way of attaching timber frame walls to an existing wall, enable flexible adjustment to different heights and offer additional support for the facade. The invention is used for the assembly of prefabricated elements in front of an existing building, for example timber frame walls with insulation, facade, built-in windows, etc.

Angle systems are often used when assembling timber frame walls because they enable quick and accurate installation. There are different types of angle systems that are suitable for different requirements and designs. Static angle systems are preferred. However, a disadvantage of static angle systems for the assembly of suspended insulated timber frame walls for energy-saving renovation is that they are usually not variable. Static angle systems are designed for a specific wall thickness and wall texture and usually cannot be adjusted to compensate for uneven or uneven walls, for example. This can cause problems if the existing wall is not perfectly straight or level. An uneven wall can mean that the timber frame wall cannot be installed in the desired position, which in turn can affect the insulation effect. Finally, static angle systems often require greater precision during installation because it can be difficult to adjust them after assembly.

The fastening of conventional wall elements to a facade is currently carried out using conventional steel angles, which are mounted into the edges of the concrete ceilings using heavy-duty anchors. Cranes are required for this and the fastening takes place while the element is hanging on the crane and being aligned. Another disadvantage is that you have to wait for the heavy-duty mortar of the anchors to set.

The invention is therefore based on the object of eliminating the disadvantages of the prior art and providing a variable, height-adjustable heavy-duty angle system that offers a high level of adaptability, facilitates assembly and is extremely durable and stable. The height-adjustable heavy-duty angle system according to the invention represents a significant departure from the prior art.

The problem is solved by the features of the independent claims. Advantageous embodiments are described in the dependent claims.

According to the invention, a two-part heavy-duty angle system with a wall rail and a mounting bracket is provided. The wall rail has a centrally arranged longitudinal adjustment bar to enable precise and reliable height adjustment.

In the sense of the invention, a wall rail refers to a component that is used to attach suspended, insulated timber frame walls. It is an elongated rod or rail that is attached along the wall (vertically). For this purpose, the wall rail has fastening holes that are usually positioned at predetermined distances from one another to enable stable and secure anchoring.

The adjustment bar in the sense of this invention refers to an elongated bar or rail which is arranged in the middle of its longitudinal direction on the wall rail.

In a preferred embodiment, the adjustment bar is mounted separately on the wall rail, preferably welded. In a further preferred embodiment, the adjustment bar is already integrated into the wall rail and thus forms a seamless, coherent component.

In order to ensure maximum stability and load-bearing capacity of the heavy-duty angle system, the system also has a mounting bracket, which is provided with cross braces for further stabilization. The mounting bracket is attached to the wall rail and runs at a right angle to it. In the sense of the invention, the mounting bracket is made of the same galvanized steel as the heavy-duty angle and has has sufficient strength and stability to be able to absorb the forces that act on the heavy-duty bracket when fastening the timber frame wall. By moving the fastening bracket along the adjustment bar of the wall rail, the height of the heavy-duty bracket can be continuously adjusted. This ensures simple, precise and safe installation of the suspended, insulated timber frame wall and enables optimal adaptation to the conditions on site.

The use of the height-adjustable heavy-duty bracket enables quick, efficient and precise assembly of suspended, insulated timber frame walls as part of energy-saving renovation measures. The heavy-duty bracket is robust and durable and ensures secure fastening of the timber frame walls.

In a further aspect, the invention relates to a mounting bracket that is configured to be attached to a wall rail in an almost infinitely variable manner and is removable. A particular advantage of this mounting bracket is therefore its removable nature. The connection between the mounting bracket and the wall rail and the attachment of the wall rail itself can be removed without great effort, even after years of use. This makes it possible to dismantle the metal screw connections and replace them with new ones without damaging the wall rail or the mounting bracket itself. This not only contributes to the longevity and reusability of the system, but also enables sustainable use in the sense of the cradle-to-cradle principle. The cradle-to-cradle system aims to design products and materials in such a way that they can be reused or recycled at the end of their life cycle without having a harmful impact on the environment. The removable nature and the ability to replace components make the mounting bracket described here a promising element for sustainable construction and assembly solutions.

In a further aspect, the invention is designed to support heavy loads in the range of 200 to 800 kg, preferably supporting loads between 300 and 600 kg, and particularly preferably supporting a load in the range of 350 to 370 kg. The heavy-duty angle system is capable of supporting heavy loads with the highest efficiency and safety, making it ideal for demanding applications in industry, construction or other areas. The load capacity of the heavy-duty angle system depends on the steel thickness. For example, the load capacity for a steel thickness of 6 mm is 310 kg.

In preferred embodiments, the heavy-duty angle has a steel thickness in the range of 4 to 20 mm, preferably 12 to 16 mm. The flexible range for steel thicknesses allows the heavy-duty angle to be adapted to different requirements. Depending on the application, choosing the optimal steel thickness can help maximize the load-bearing capacity. By adapting the steel thickness to the specific requirements of a project, material costs can be optimized. In some cases, choosing a thin steel thickness can increase resource efficiency and contribute to more sustainable use by using less material. In certain applications, a thicker steel thickness can provide additional safety, especially when dealing with heavy loads or extreme stresses.

In a preferred embodiment, the wall rail has a length in the range of 300 to 800 mm, preferably a length of 500 to 700 mm and particularly preferably a length of 650 mm. The length of the wall rail is a crucial feature as it has a direct influence on the stability, flexibility and functionality of the construction.

In a further preferred embodiment of this invention, the wall rail is equipped with a special fastening system that enables secure anchoring in the subsurface. For mineral subsurfaces, this fastening system uses either plastic dowels and screws or, alternatively, reaction resin dowels in combination with threaded bolts. For wooden subsurfaces, e.g. half-timbering, timber construction bolts are used to fasten the wall rail to the subsurface of the existing structure. Chemical dowels and threaded bolts (anchors) can also be used. This type of fastening offers high strength and load-bearing capacity and is therefore particularly suitable for use in heavy constructions such as the height-adjustable heavy-duty angle. In the sense of the invention, chemical dowels consist of two components: an anchor and an injection mortar. The chemical dowels are activated by injecting the mortar into a pre-drilled hole. The mortar then hardens and forms a firm connection with the anchor. This ensures a stable and secure fastening that can withstand high loads.

Possible substrate materials to which this fastening system can be attached include materials such as concrete, solid brick masonry, porous brick masonry, perforated brick masonry, wood, natural stone, Steel, aluminum and combinations of these materials.

The number of fasteners per base rail is influenced by two decisive factors: the load that the facade to be installed must bear, including any traffic loads, and the permissible load transfer per fastening point into the subsurface.

The fastening points or fastening holes are positioned on the long edges of the wall rail. These fastening points are arranged in such a way that, due to the offset of the dowels in the masonry substrate, only one dowel is positioned per brick. In other materials, this allows the dowel spacing in the material to be optimized. This leads to significant advantages in load transfer compared to an arrangement without offset. The fastening holes are offset from one another, at a distance of 50-150 mm, preferably at a distance of 80-120 mm, particularly preferably 90-110 mm.

Four plastic dowels have been proven to be sufficient to provide the required stability, however there is the possibility of using up to 12 dowels depending on the specific requirements of the construction project.

Another important aspect of this design is the independence of the mounting of the base rail from the mounting bracket. This enables efficient installation and gives the construction flexibility.

In addition, the wall rail is equipped with metric threaded T-nuts or slotted screws located in the middle of the rail. These can be moved almost the entire height of the rail. This feature allows for precise adjustment and positioning of components and parts along the rail and contributes to the versatility and adaptability of this innovative design.

In a further preferred embodiment of this invention, the fastening bracket is connected to the wall rail by means of at least one fastening means, preferably at least two screws. Fastening is carried out using washers and nuts (for the slot screws) or washers and screws (for the slot nuts), which ensures a secure and stable connection. A significant advantage of this embodiment is that fastening can be carried out continuously in the vertical direction, i.e. in height.

Using washers and nuts or washers and bolts provides a robust and reliable method of securing the mounting bracket to the wall rail. These fasteners can be combined to ensure optimum stability and adaptability.

The stepless height adjustment is a significant feature of this design as it allows precise positioning and adjustment of the mounting angle. This is particularly important in construction and assembly applications to ensure that the design meets the specific requirements and conditions.

A particularly preferred embodiment of the wall rail, which also serves as a guide rail, is one in which the rail is milled from solid steel. This embodiment is preferred in that it does not lead to thermal distortions. This guide rail therefore has an elongated hole in which the mounting bracket can be screwed continuously and thus secured.

• 1 Schematische Darstellung einer bevorzugten Ausführungsform der erfindungsgemäßen Wandschiene mit geschweißter Verstell-Leiste
• 2a Schematische Darstellung einer bevorzugten Ausführungsform der erfindungsgemäßen Wandschiene mit integrierter Verstell-Leiste in Draufsicht
• 2b Schematische Darstellung einer bevorzugten Ausführungsform der erfindungsgemäßen Wandschiene mit integrierter Verstell-Leiste in Seitenansicht
• 3a Schematische Darstellung einer bevorzugten Ausführungsform des erfindungsgemäßen Befestigungswinkels
• 3b Schematische Darstellung einer bevorzugten Ausführungsform des erfindungsgemäßen Schwerlastwinkelsystems in Seitenansicht und Frontalansicht
• 4 zeigt Fotografie des zusammengesetzten erfindungsgemäßen höhenverstellbaren Schwerlastwinkelsystems
• 5a, 5b zeigen eine bevorzugte Ausführungsform der Wandschiene, hergestellt durch Fräsen aus einem Vollmaterial

The invention will now be described by way of example with reference to figures, without however being limited to these; it shows:

• 1 Schematic representation of a preferred embodiment of the wall rail according to the invention with welded adjustment bar
• 2a Schematic representation of a preferred embodiment of the wall rail according to the invention with integrated adjustment bar in plan view
• 2 B Schematic representation of a preferred embodiment of the wall rail according to the invention with integrated adjustment bar in side view
• 3a Schematic representation of a preferred embodiment of the mounting bracket according to the invention
• 3b Schematic representation of a preferred embodiment of the heavy-duty angle system according to the invention in side view and front view
• 4 shows photograph of the assembled height-adjustable heavy-duty angle system according to the invention
• 5a , 5b show a preferred embodiment of the wall rail, manufactured by milling from a solid material

Detailed description of the figures

1 shows a wall rail (10) according to the invention, which is available in different designs, preferably in designs from 400 mm to 800 mm. In this preferred embodiment, the adjustment bar (12) is welded onto the wall rail (10). The rail (10) is firmly connected to the subsurface of an existing building using plastic dowels and screws or using commercially available reaction resin dowels and threaded bolts and is thus fastened to the building. The number of fastening elements per base rail depends on A) the load of the facade to be installed (including traffic loads) and B) the permissible load transfer into the subsurface per fastening point. For this purpose, fastening points (11) are provided on the longitudinal edges of the wall rail (10). The arrangement of the fastening points (11) (hole diameter 11 mm) is such that the dowel is always in a stone due to their offset. Usually 4 plastic dowels are sufficient. However, it is possible to use up to 12 dowels. The wall rail (10) can be mounted first, regardless of the mounting bracket (13) to be used.

2a and 2 B show a further preferred embodiment of the wall rail (10), wherein the adjustment bar (12) is already integrally integrated into the wall rail (10). In this configuration, the fastening holes (11) in the wall rail (10) are arranged such that they are 100 mm apart.

3a , 3b and 3c show a preferred embodiment of a mounting bracket (13) with stabilizing cross braces (15) in different views, which is connected and fastened to the wall rail (10) (not shown in this figure) by means of washers and nuts or washers and screws. The fastening to the wall rail can be made infinitely variable in height within the given limits. It is an elongated rod or rail that is attached along the wall (vertically). For this purpose, the mounting bracket (13) has fastening holes (14), which are usually positioned at predetermined distances from one another to enable stable and secure anchoring.

4 shows a photograph of the assembled height-adjustable heavy-duty angle system according to the invention.

5a and 5b show a preferred embodiment of the wall rail 10, which also serves as a guide rail. An opening 16 is provided for the insertion of screws. In this embodiment, the manufacturing method is different, namely such that the rail is milled from a solid material, i.e. not welded. This embodiment is preferred in that it does not lead to thermal distortions that may occur during welding. The guide rail therefore has an elongated hole in which the mounting bracket can be screwed continuously using screws and is thus fastened.

List of reference symbols

10

Wall rail

11

Fixing points/ fixing holes for fixing to the building substrate

12

Adjustment bar

13

mounting brackets

14

Fixing points/ fixing holes for fixing to the wall rail

15

Cross brace

16

Opening in wall rail

17

Long hole

Claims (12)

Height-adjustable heavy-duty angle system comprising a wall rail (10) with a central, longitudinally aligned adjustment bar (12), and a fastening angle (13) with a support, characterized in that - the fastening angle (13) is configured such that it is designed to be infinitely displaceable on the wall rail (10) and can be mounted in a removable manner - and that the heavy-duty angle system is designed and constructed such that it carries heavy loads of 200 - 800 kg, preferably 300 - 600 kg, particularly preferably 350 - 370 kg. Height-adjustable heavy-duty angle system according to Claim 1 , characterized in that the adjustment bar (12) is integrated into the wall rail (10) Height-adjustable heavy-duty angle system according to Claim 1 , characterized in that the adjustment bar (12) has a length in the range of 300 to 700 mm, preferably a length of 400 to 600 mm and particularly preferably a length of 550 mm. Height-adjustable heavy-duty angle system according to one of the preceding claims, characterized in that the wall rail (10) and the fastening angle (13) have a steel thickness of 4-20 mm, preferably a steel thickness of 12-16 mm. Height-adjustable heavy-duty angle system according to one of the preceding claims, characterized in that the wall rail (10) has a length in the range of 400 to 800 mm, preferably a length of 500 to 700 mm and particularly preferably a length of 650 mm. Height-adjustable heavy-duty angle system according to at least one of the preceding claims, characterized in that the wall rail (10) is milled from a solid steel material and has an elongated hole extending over the length of the wall rail, which serves for the stepless fastening of the fastening angle. Height-adjustable heavy-duty angle system according to one of the preceding claims, characterized in that the fastening angle (13) can be connected to, on and with the wall rail (10) with at least one fastening means, preferably with at least two screws. Height-adjustable heavy-duty angle system according to one of the preceding claims, characterized in that the wall rail (10) comprises fastening holes (11) along the longitudinal edges for fastening to the substrate. Height-adjustable heavy-duty angle system according to one of the preceding claims, characterized in that the fastening holes (11) are arranged offset from one another, at a distance of 50-150 mm, preferably at a distance of 80-120 mm, particularly preferably 90-110 mm. Height-adjustable heavy-duty angle system according to one of the preceding claims, characterized in that the fastening angle (13) is stabilized by means of cross braces (15). Set comprising a height-adjustable heavy-duty angle system according to the Claims 1 until 9 , comprising at least one wall rail (10) with adjustment bar (12), and a fastening bracket (13). Set after Claim 11 , characterized in that the heavy-duty angle system comprises dowels and/or corresponding screws for fastening the wall rail to the fastening angle and for fastening in the substrate.

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