DE10302983A1 - Building material formed from thermal layer between two sections with an area between the two profiles, meets fire, weight, insulation and is simple and fast to build with as well as being cost-effective - Google Patents

Abstract

The building material is formed from a thermal layer (9) between two sections (2) with an area between the two profiles which is fully filled with thermal material (12) made from mineral fibers e.g. rockwool. The thermal material has a density of between 50-130 kg/m3 and a connectivity of between 0.5-2% mass. The thermal material has a surface (13) with a layer (14) of glass fiber sealing layer. The thermal mat has coverings (7) with legs (5) fixed to the sections. Screws (16) or nails hold the layers together.

Description

The invention relates to a building wall with a scaffolding, consisting from at least two spaced apart, preferably perpendicular aligned, in particular in cross-section C, U, W or Ω-shaped Profiles, the two essentially parallel legs and have a web connecting the legs, at least one unilateral, in particular attached to the profiles Cladding, preferably in the form of plasterboard and / or gypsum fiber boards, and one extending between the profiles, between the Legs plugged in heat and / or soundproofing from an insulation layer.

Building walls of this type are known from the prior art. These are non-load-bearing inner walls, which are designed as partition walls with weights per unit area of up to 1.5 kN / m ² and, in contrast to wall structures made of bricks, stones or aerated concrete elements using mortar or adhesive, are called assembly walls. This naming already describes the assembly of the components in the dry state (drywall) during the assembly of the individual components.

Generic building walls are predominantly by their own weight claimed and are not integrated into the static concept of a building. You need to however acting on their surface personnel record and introduce into the adjacent load-bearing components. Deformations of the adjacent components must not lead to constraining stresses lead in the non-load-bearing building walls, so that these building walls through Expansion joints must be separated from the adjacent components.

Generic building walls must meet certain requirements with regard to sound, heat and fire protection. In particular, high sound insulation properties and at least one fire resistance class F30 according to DIN 4102 part are intended 4 be achieved. But there are also known building walls that can withstand fire exposure for up to 180 minutes due to appropriate fire protection constructions and are therefore fire-resistant with a correspondingly higher classification of the fire resistance classes. Corresponding requirements for the resistance of the building wall in the event of a fire mean that certain building materials, particularly in the area of the load-bearing construction elements, may not be used if these building materials lose their stability in the fire or make an active contribution to the fire.

Building walls in question here, which made up metallic stand and gypsum plasterboard are described in DIN 18 183. It is between single and double stud walls, as well as free-standing facing shells distinguished. According to DIN 18 183 there is a single standard wall a substructure arranged in one level with stands that are planked on both sides with plasterboard panels as cladding. With the double stud wall are the stands arranged in two parallel planes and only on the two outer sides covered with plasterboard cladding. Freestanding Facing shells consist of a substructure arranged in one level stands and a one-sided cladding made of plasterboard.

The stands are profiled as C or U profiles referred to, whereby the C profiles of The U-profiles differ in that the free ends of their legs are crimped one or two at a time. Be complementary the letters "W" or "D" to the letters "C" or "U" attached, if the profiles are used as wall profiles (W) or ceiling profiles (D). The flanging the free ends of the webs serve to stiffen the profiles alternatively or additionally also by beads in the area of the web or also in the area the leg can be achieved. The beads also make one smaller contact area achieved on the cladding elements so that the sound energy in the area of the contact surfaces reduced between cladding and profile. Alternatively, on the thighs on the outside punctiform surveys arranged to be a distance between the legs and the Adjust cladding elements.

In the area of the beads can also Cables are laid.

The profiles are on the floor or on the ceiling with the help of doweled screws or through Nailable Plug attached. The pivot pin dowels separate over here a cylindrical plastic sleeve the metallic core of the profile to the transmission of structure-borne noise to reduce. In the event of a fire, the metal pin fixes the profile and with it the building wall even if the plastic has melted or burned. Preferably is the distance between the individual attachment points is approximately one Meter. In a building wall is common a profile on the floor and a profile on the ceiling opposite arranged so that there is a vertically aligned building wall already results when the cladding elements on one leg of the ceiling profile and the opposite Leg of the floor profile are attached.

Sealing elements must be inserted between the profiles fastened to the floor and the ceiling and the adjacent components, for example the floor and the ceiling, in order to provide both a soundproof seal and a seal that is largely sealed against fire and smoke to build the adjacent components and the building wall. Appropriate seals must be designed to be compressible in order to be able to compensate for unevenness of the adjacent components to a certain degree. As a result, both compressible sealing tapes made of foam, putty or very often strips of mineral wool insulation material in thicknesses of approx. 10 to approx. 20 mm can be used.

In the in the floor area and on the U-profiles attached to the ceiling become vertically aligned profiles, so-called stand profiles used, the legs of these stand profiles in a building wall have essentially the same orientation, i.e. that the legs of the stand profiles aligned to the web of an adjacent stand profile are. Is a stand profile in the area of an adjacent component, for example a load-bearing one Wall is arranged, this stator purple is in the same way attached to the load-bearing wall, like the U-profiles described above in the area of floor and ceiling.

As a rule, the stand profiles friction held in the U-profiles on the ceiling and floor, with the stand profiles arranged at a distance from the web of the U-profile fastened on the ceiling are to a relative movement of the upright profiles to the U-profiles to enable. additional can the stand profiles but are connected to each other by so-called blind rivets, if cross bolts for openings or other internals are used. Usually will the stand profiles but through the cladding elements with the ceiling and floor arranged U-profiles fixed.

Plasterboard is used as cladding elements in the varieties Gypsum cardboard (GKB) or fire protection boards (GKF) or gypsum fiber boards used. Such plates are of different material thicknesses and with lengths known between 2000 and 4000 mm with a gradation of 250 mm, the width of such plates is constant at 1250 mm. at thicknesses The maximum length of such plates is more than 18 mm 3500 mm limited, these plates with widths of 600 mm or 1250 mm can be offered. Due to the dimensions of the plates and the preferred upright installation position has a distance between adjacent column profiles of 62.5 cm proved to be particularly advantageous, so that the plates with their two longitudinal edges two stand profiles and complementary are attached to a third stand profile with the central region. The panels are connected to the upright profiles by means of fast construction screws according to DIN 18 182, Part 2 “Accessories for processing of plasterboard - drywall screws ".

The cavity between neighboring ones upright profiles on the one hand and the cladding elements on the other hand insulation layers filled, the usual from individual insulation boards with greater Stiffness exist. These insulation boards will be inserted on the one hand between the legs of a support profile until the narrow sides of the insulation boards rest on the inside of the web.

On the other hand, the insulation boards with their opposite Narrow side to the outside of the web of the neighboring column profile created. Filling out of the cavities with individual insulation boards leads to excellent insulation results, but due to the installation of the relatively rigid insulation panels between the legs of the carrier profiles an elaborate and possibly insufficiently performed work represents.

Based on this state of the art the invention is therefore based on the object of a building wall to further develop such that their creation, in particular assembly is significantly simplified and accelerated, so that an inexpensive assembly with at least equally good insulation results.

The solution to this problem provides that the insulation layer between two profiles from at least one the space between the Profiles completely filling insulating mat is made of mineral fibers, especially rock wool.

Such an insulation mat is much faster and easier to insert in the space between the profiles. By a higher one flexibility such an insulation mat processing is significantly simplified. So can too Bumps in the area between the profiles or in particular be easily balanced in the area of the cladding elements.

According to a further feature of the invention, it is provided that the insulation mat has a bulk density between 50 and 130 kg / m ³ . Such an insulation mat is sufficiently flexible and easy to handle, and such insulation mats can be delivered to the construction site in rolled form.

It is also contemplated that the insulating mat has a binder content between 0.5 and 2% by mass, so that the mineral fibers are just loosely connected are. This configuration also contributes to the insulation mat highest Degree of flexibility when installing between the profiles.

It is preferably provided that the insulation mat has a lamination made of a glass fiber fleece or a textile glass fiber fabric on at least one surface, the insulation mat preferably being sewn to the lamination. Such a lamination contributes to the stability and dimensional stability of the insulation mat, but at the same time still allows the insulation mat to be highly flexible in terms of its shape and its ability to be installed between the profiles. The sewing of the glass fiber fabric or the glass fiber fleece to the insulating mat is also advantageous here that the connection between these two elements is only selective. An alternative possible gluing of the lamination to the insulation mat should only take place over part of the area in order to avoid excessive stiffening of the insulation mat. With partial gluing, the flexibility of the insulation mat is largely retained.

Alternatively, the insulation mat on at least one surface have a wire mesh that is quilted with the insulation mat. The Wire mesh has only a low bending stiffness, so that this also gives flexibility and flexibility of the insulation mat not significantly affected the insulation mat but still considerably simplified in the space between the profiles preferably after one-sided installation of the cladding elements can be installed.

According to another feature of the invention provided that the insulation mat is clamped between cladding elements, the opposite Legs of the profiles are attached. This is how the entire space between the cladding elements filled with the insulation mat and the clamping bracket of the insulation mat prevents a later Slip and collapse of the insulation layer.

It is also contemplated that the insulating mat on holding devices arranged in the profiles and / or the cladding suspended is. This Ausgestal device serves for simplified installation between the stands and on the other hand securing the insulation mat in the desired and prescribed position within the building wall. The holding device is preferably as at even intervals of preferably 25 to 50 cm arranged screws or nails. These screws are preferably directly below a ceiling profile introduced into the cladding, the free ends of the screws or Nails in the space between the profiles protrude and to hang the insulating mat serve.

The holding devices preferably engage the surface of the insulation mat formed with the lamination, so that the lamination added accomplished the task the insulation mat even in the suspended Stabilize condition. The lamination also prevents that the insulation mat during the Installation in the area of its side surface facing the ceiling tears out and additionally through Pruning must be edited.

According to another feature of the invention provided that the insulation mat at least in its upper area with at least one cladding glued or over a Velcro is connected to the panel. For gluing the insulation mat the cladding can For example, double-sided adhesive tapes can also be used tapes have proven to be advantageous on a plastic basis. A special one easy-to-use embodiment provides a Velcro tape, with part of the Velcro tape on the Fairing and the counterpart of the Velcro tape on the insulation mat fixed, for example sewn on is. Such an arrangement has the advantage that the position of the insulation mat between the profiles during assembly by simply loosening it the two Velcro elements removed from each other and corrected can be.

Finally, after another Feature of the invention provided that the insulation mat has a material thickness, which is preferably 1 to 2 cm larger than the distance between the two legs of the profile. This will completely fill out the Cavity between the profiles on the one hand and the cladding elements on the other hand in a simple manner, the insulation te one appropriate flexibility, i.e. Compressibility in Direction of the surface normal their big surfaces has and because of this compressibility over the entire surface of the inner surfaces of the Cladding elements are applied.

Other features and advantages of Invention result from the following description of a preferred embodiment, as shown in the drawing.

The drawing shows a section of a building wall 1 in a cut top view. The building wall has a scaffolding, two of which are spaced apart profiles 2 are shown with a C-shaped cross section. Each profile has a web 3 with a flat bead 4 and two legs arranged at right angles to the web 5 on, the free ends of which are aligned flanges 6 to have.

The spaced profiles 2 are aligned in the same direction, ie each profile 2 is with its footbridge 3 an adjacent profile 2 facing.

On the outer surfaces of the legs 5 are cladding elements 7 screwed in the form of plasterboard. For this, reach through the screws 8th the cladding elements 7 and the thigh 5 of the profile 2 , In the drawing there is only one side of the cladding elements 7 shown, with the building wall usually on both sides with cladding elements 7 is formed, unless it forms a facing.

Between neighboring profiles 2 is an insulation layer 9 arranged with a longitudinal side surface 10 between the thighs 5 of a first profile 2 is inserted such that the side surface 10 on the inner surface of the footbridge 3 is applied. With a second side surface 11 lies the insulation layer 9 on the outer surface of the footbridge 3 of the second profile 2 at, the insulation layer 9 can be slightly compressed in its direction transverse to its longitudinal direction, so that the insulation layer 9 jamming between the profiles 2 is arranged.

The insulation layer 9 is as an insulation mat 12 trained which insulation mat 12 the space between the profiles 2 completely filled and made of mineral fibers. The insulation mat 12 has a bulk density between 50 and 130 kg / m ³ with a binder content between 0.5 and 2% by mass.

On one surface 13 the insulation mat 12 is a lamination 14 arranged in the form of a glass fiber fleece, the glass fiber fleece with the insulating mat 12 is sewn. In this regard, there are connection points in the drawing 15 between the lamination 14 and the insulation mat 12 shown.

Through the cladding elements 7 are screws 16 screwed in as a holding device, the length of which is at least twice as great as the material thickness of the cladding elements 7 , The screws 16 thus protrude into the space between the profiles 2 intervene and reach into the insulation mat 12 on. It can be seen that the insulation mat 12 is oriented so that the surface 13 with the lamination 14 the free ends of the screws 16 is facing. The screws are at least in an area of the building wall facing a building, not shown 1 arranged so that the insulation mat 12 hanging in the space between the profiles 2 is arranged.

Finally it can be seen that the insulation mat 12 has a material thickness that is approx. 1 cm larger than the clear distance between the two legs 5 of the profile 2 , The insulation mat 12 has a sufficiently high compressibility for the above-mentioned values for the bulk density and the binder content, so that the insulation mat 12 with additionally installed cladding elements 7 on the opposite side of the building wall 1 full surface on the inner surfaces of the cladding elements 7 is applied.

Claims (11)

Building wall with a support structure, consisting of at least two spaced apart, preferably vertically aligned, in particular cross-sectionally C, U, W or Ω-shaped profiles, which have two essentially parallel legs and a web connecting the legs , an at least one-sided, attached to the profiles and in particular attached cladding, preferably in the form of plasterboard and / or gypsum fiber boards, and an extending between the profiles, inserted between the legs thermal and / or acoustic insulation from an insulating layer, thereby characterized that the insulation layer ( 9 ) between two profiles ( 2 ) from at least one the space between the profiles ( 2 ) completely filling insulation mat ( 12 ) is made of mineral fibers, especially rock wool. Building wall according to claim 1, characterized in that the insulating mat ( 12 ) has a bulk density between 50 and 130 kg / m ³ . Building wall according to claim 1, characterized in that the insulating mat ( 12 ) has a binder content between 0.5 and 2% by mass. Building wall according to claim 1, characterized in that the insulating mat ( 12 ) on at least one surface ( 13 ) a lamination ( 14 ) made of a glass fiber fleece or a textile glass fiber fabric, the insulation mat ( 12 ) with the lamination ( 14 ) is preferably sewn. Building wall according to claim 1, characterized in that the insulating mat ( 12 ) on at least one surface ( 13 ) has a wire mesh that is connected to the insulation mat ( 12 ) is quilted. Building wall according to claim 1, characterized in that the insulating mat ( 12 ) between cladding elements ( 7 ) is clamped on the opposite legs ( 5 ) the profiles ( 2 ) are attached. Building wall according to claim 1, characterized in that the insulating mat ( 12 ) on in the profiles ( 2 ) and / or the cladding arranged holding devices is suspended. Building wall according to claim 7, characterized in that the holding devices as screws arranged at regular intervals of preferably 25 to 50 cm ( 16 ) or nails. Building wall according to claim 7, characterized in that the holding devices in the with the lamination ( 14 ) provided surface ( 13 ) the insulation mat ( 12 ) intervene. Building wall according to claim 1, characterized in that the insulating mat ( 12 ) is glued at least in its upper area with at least one cladding or connected to the cladding via a Velcro strip. Building wall according to claim 1, characterized in that the insulating mat ( 12 ) has a material thickness that is preferably 1 to 2 cm larger than the distance between the two legs ( 5 ) of the profile ( 2 ).