AT520058A1 - T profile - Google Patents

Abstract

The invention relates to a T-profile (1) for drywall with two lateral flanges (12) and a normally aligned web (11). According to the invention, it is provided that the T-profile (1) is formed from a one-piece, folded flat element, in particular a rolled product, wherein the web (11) is formed from two web layers (11a, 11b) which are attached to a vertex (14). are connected to each other and at their foot (15) are each connected to one of the flanges (12).

Description

The invention relates to a T-profile for drywall construction according to the preamble of patent claim 1.

A variety of different profiles are used in drywall construction. They are intended to ensure that surface components can be assembled safely and stably. Among other things, T-profiles are used, which are made of solid steel. These T-profiles are heavy and expensive to produce.

The object of the invention is to provide a profile for dry construction, which enables a particularly stable construction, has a low weight and can be produced inexpensively.

The invention solves the problem with the characterizing feature of patent claim 1.

According to the invention, it is provided that a T-profile is provided which is formed from a one-piece, folded flat element, the web being formed from two web layers which are connected to one another at an apex and which are each connected to one of the flanges at their base are. The use of a T-profile is particularly advantageous for drywall construction, especially for the construction of drywall ceilings. Surface components, e.g. Insulation boards can rest on the flanges of the T-profile and can thus be securely fixed. The surface component can be attached so that it extends to the web. For a flat construction, it is therefore possible for surface components to be attached on both sides of the web in such a way that they are only spaced apart by the web width. Flat constructions are particularly important for insulation, because gaps in the construction impair the effect of the insulation. The T-profile according to the invention allows a maximum approximation of two components. This creates a particularly stable surface construction.

Furthermore, the T-profile can be produced at a very low cost by being formed from a one-piece, folded flat element. A rolled product is particularly suitable as a flat element, it being possible to use sheet metal or flat steel. This significantly reduces the weight of the T-profile. The fact that the web is made up of two layers gives the T-profile particular stability.

In order to obtain a particularly stable construction, it is advantageous if the height of the T-profile is less than the width of the T-profile. The height should be at least 30% of the width. The height of the T-profile is assumed to be the distance from the foot to the apex. The width of the T-profile is defined as the distance between the edges of the flanges facing away from the web. For use in drywall construction, it is particularly advantageous if the height corresponds to 40% - 50% of the width, since particularly stable structures can be obtained in this way.

Alternatively, it is advantageous if the height corresponds to 75% - 85% of the width. A T-profile that is designed in this way can also provide adequate stabilization for surface components with a greater thickness. Such surface components with greater thickness can be insulation layers, for example.

A particularly advantageous T-profile is obtained by arranging the web layers parallel to one another. This arrangement enables a particularly stable construction. It is particularly advantageous if they are arranged parallel to one another over the entire height. Alternatively, the web layers can be folded towards one another so that they enclose an angle between 0 ° and 5 ° at the apex. This makes it possible to bring surface components as close together as possible in order to create flat structures.

It can be provided that the web layers are continuously spaced apart from one another. This enables a particularly cost-effective production of a T-profile.

In addition, the T-profile can be designed so that it is reversibly compressible along its width, i.e. that the surfaces of the flanges can be brought together. The web layers can then at least partially abut one another, in particular in the region of the foot. The reversible compression means that surface components in drywall constructions can be stabilized, since the T-profile can spread out against adjacent surface components.

It can be provided that the T-profile is isosceles, in particular that it is designed symmetrically to the web. In this way, particularly stable constructions are made possible.

A T-profile can be designed to be particularly stable if the edges of the flanges facing away from the web are bent to form flange edges. The flange edges can then be arranged on the side of the web and normal to the surfaces. Likewise, the flanges on their side facing away from the web can be delimited by flange edges and the flange edges can be bent in the direction of the apex and can be aligned normally to the surfaces of the flanges. A T-profile designed in this way is particularly stable. In addition, surface components that rest on the flanges of the T-profile can be held in their position.

It is particularly advantageous if the flange edges have a height which corresponds to 5% to 25% of the height of the web. This results in particularly stable T-profiles. It is also possible to stabilize surface components that rest on the flanges by means of the flange edges.

It is particularly advantageous if the T-profile consists of a one-piece, folded sheet. This enables simple and cost-effective production of the T-profile. The weight of the T-profile can be minimized.

A T-profile according to the invention can be used, for example, in a suspension device for dry construction ceilings. A suspension device for drywall ceilings with a T-profile and a vernier hanger is particularly advantageous, comprising a vernier upper part and a vernier bracket, the T-profile being mounted in the vernier bracket. This gives the suspension device great stability. Lateral slipping or tilting can be prevented. The T-profile is advantageously oriented such that the apex points in the direction of the upper part of the vernier. This makes the suspension device particularly stable and can provide a stable contact surface for surface components.

The vernier hanger enables flexible distance adjustment between the suspended ceiling and the load-bearing ceiling. The suspension device can therefore be flexibly adapted to the individual circumstances.

Another aspect of the invention provides a ceiling construction for dry construction ceilings that has at least one suspension device and at least one first insulation layer that rests on the flanges of the T-profile. Such a ceiling construction is particularly stable. Because the insulation layer lies on the flanges of the T-profile, it can be fixed particularly securely. The insulation layer can extend to the web. The insulation is only interrupted by the width of the web. The result is a flat, flat insulation construction, through which a particularly advantageous insulation can be achieved.

Furthermore, a ceiling construction can be provided which has a further insulation layer on the side of the vernier bracket facing away from the vernier upper part. This further insulation layer can be attached to the side of the vernier bracket facing away from the vernier upper part. The further insulation layer can also be attached to the underside of a T-profile according to the invention, that is to say on the side of the flanges facing away from the web. This gives the ceiling construction a particularly good insulation effect.

It can be provided that the ceiling structure has at least one U-profile, via which the ceiling structure is laterally connected to a wall, the first insulation layer lying in the U-profile. In this way, a particularly stable ceiling construction is obtained.

The invention is illustrated by way of example with reference to the following drawings without restricting the general inventive concept:

1 shows an exemplary embodiment of a T-profile according to the invention.

Fig. 2 shows an exemplary ceiling construction that includes a T-profile according to the invention.

1 shows an embodiment of a T-profile 1 according to the invention. The T-profile 1 shown is formed from a one-piece, folded sheet metal. The web 11 is formed from two web layers 11a, 11b which are connected to one another at the apex 14. At the base 15, the flanges 12 connect to the web 11 and are aligned normally to the web 11. The radius of the folds is 0.5 mm in the illustrated embodiment. In the embodiment shown, the web layers 11a, 11b are spaced apart from one another over the entire height, that is to say from the base 15 to the apex 14. The distance is 1 mm in the illustrated embodiment. The web layers 11a, 11b run parallel to one another. They are reversibly compressible, i.e. The web layers 11a and 11b can be brought closer to one another by lateral pressure, so that they abut one another in the area of the foot 15. At the end of printing, the T-profile 1 returns to its starting position.

The height of the web 11 or the height of the T-profile 1 is less than the width of the T-profile 1. The width is understood as the distance between the sheet edges that form the outer end of the flanges 12. In the embodiment shown, the height corresponds to 45% of the width.

The T-profile 1 is symmetrical to the web 11. The web layers 11a, 11b are of the same height. The T-profile 1 is isosceles and the flanges 12 each have the same width and lie in one plane.

The sheet metal edges are bent, the bent edges corresponding to 15% of the width of the flanges 12. The bent edges form flange edges 13. The flange edges 13 are normal to the surface of the flanges 12, being arranged on the side of the web 11. The height of the flange edges 13 corresponds to 20% of the height of the web in the embodiment shown.

An exemplary ceiling construction is shown in FIG. A T-profile 1 according to the invention is formed from a folded sheet in the embodiment shown. The web 11 has two web layers 11a, 11b which are arranged parallel to one another. The height of the web 11 corresponds to 80% of the width of the T-profile 1. The T-profile 1 is isosceles. At the edges of the flanges 12, which are formed on the side facing away from the web 11, the flanges 12 are delimited by flange edges 13. The flange edges 13 are bent in the direction of the apex 14 and aligned normal to the surface of the flanges 12. The height of the flange edges 13 corresponds to 10% of the height of the web in the embodiment shown.

The T-profile 1 is stored in a vernier hanger. The vernier hanger has a vernier upper part 21 and a vernier bracket 22, which are connected by a vernier split pin 23. The T-profile 1 is arranged so that the apex 14 points in the direction of the vernier upper part 21. The vernier upper part 21 is mounted on the ceiling 4 via a ceiling fastening 34. In the embodiment shown, the ceiling fastening consists of an anchor nail.

The ceiling construction has a first insulation layer 311. In the illustrated embodiment, the first insulation layer 311 consists of mineral wool. The first insulation layer 311 lies on the flanges 12 of the T-profile 1. The first insulation layer 311 is mounted on the wall 5 in a U-profile 32. The U-profile 32 is mounted on the wall 5 with a wall fastening 33. In the illustrated embodiment, the wall fastening 33 is designed as an anchor nail. A drywall connection seal 34 is attached between the U-profile and the wall.

In the embodiment shown, a further insulation layer 312 is attached below the first insulation layer 311. In the embodiment shown, the further insulation layer 312 consists of a multilayer wood wool panel. The further insulation layer 312 is attached with screws 36 to the sides of the flanges 12 of the T-profile 1 facing away from the apex 14, i.e. the further insulation layer 312 is arranged on the side of the vernier bracket 22 facing away from the vernier upper part 21. On the wall 5, the further insulation layer 312 is attached below the U-profile 32 and connected to the U-profile 32 by means of screws 36.

In addition, a third insulation layer 313 is provided in the illustrated embodiment. This third insulation layer 313 lies on top of the first insulation layer 311. The third insulation layer 313 is arranged between the first insulation layer 311 and the ceiling 4. In the illustrated embodiment, the third insulation layer 313 consists of a rock wool.

Claims (13)

Claims: 1. T-profile (1) for drywall construction with two side flanges (12) and a normally aligned web (11), characterized in that the T-profile (1) consists of a one-piece, folded flat element, in particular one Rolled product is formed, the web (11) being formed from two web layers (11a, 11b) which are connected to one another at an apex (14) and which are each connected at their base (15) to one of the flanges (12) , 2. T-profile (1) according to claim 1, characterized in that the T-profile (1) has a height which is defined as the distance from the foot (15) to the apex (14) and that the T-profile (1) has a width which is defined as the distance between the edges of the flanges (12) facing away from the web (11), the height of the T-profile (1) being less than the width of the T-profile ( 1), and corresponds to at least 30% of the width, in particular that the height corresponds to 40% - 50% or 75% - 85% of the width. 3. T-profile (1) according to one of the preceding claims, characterized in that the web layers (11a, 11b), in particular over their entire height, are arranged parallel to one another or in that the web layers (11a, 11b) at the apex (14 ) enclose an angle of 0 ° to 5 °. 4. T-profile (1) according to one of the preceding claims, characterized in that the web layers (11a, 11b) are continuously spaced from one another. 5. T-profile (1) according to any one of the preceding claims, characterized in that the T-profile (1) is so reversibly compressible along its width that the web layers (11a, 11b) are at least partially touching, in particular at least in Area of the foot (15). 6. T-profile (1) according to one of the preceding claims, characterized in that the T-profile (1) is isosceles, in particular that it is designed symmetrically to the web (11). 7. T-profile (1) according to one of the preceding claims, characterized in that the edges of the flanges (12) facing away from the web (11) are bent up to flange edges (13) and the flange edges (13) on the side of the web ( 11) and are arranged normal to the surfaces of the flanges (12) or that the flanges (12) are delimited by flange edges (13) on their side facing away from the web (11) and the flange edges (13) in the direction of the apex (14 ) bent up and aligned normal to the surfaces of the flanges (12). 8. T-profile (1) according to claim 7, characterized in that the flange edges (13) have a height which corresponds to 5% - 25% of the height of the web (11). 9. T-profile (1) according to one of the preceding claims, characterized in that the flat element is a sheet. 10. Suspension device for drywall ceilings with a T-profile (1) according to one of claims 1-9 and a vernier hanger, comprising a vernier upper part (21), and a vernier bracket (22), characterized in that the T - Profile (1) is mounted in the vernier bracket (22), the apex (14) being aligned in the direction of the vernier upper part (21). 11. ceiling construction for drywall construction comprising at least one suspension device according to claim 10, and at least a first insulation layer (311), which rests on the flanges (12) of the T-profile (1). 12. Ceiling construction according to claim 11, characterized in that a further insulation layer (312) is arranged on the side of the vernier bracket (22) facing away from the vernier upper part (21) and / or that on the side facing away from the apex (14) a further insulation layer (312) is attached to the flanges (12). 13. Ceiling structure according to one of the preceding claims, characterized in that at least one U-profile (32) is provided, via which the ceiling structure is laterally connected to a wall (5), in particular the first insulation layer (311) in the U-profile (32).