DE29808461U1 - Power anchor for composite thermal insulation systems - Google Patents

Description

Description Power anchor for thermal insulation composite systems

Task :

Increased requirements for thermal protection require ever stronger thermal insulation. Passive houses in solid construction, for example, require thermal insulation of more than 30 cm thick, and low-energy houses also require insulation thicknesses of around 15 cm. Even in such houses, it is necessary that structures such as railings, canopies, trellises, scaffolding or similar can be attached to the facade. Such structures exert tensile, compressive and transverse forces on the wall. The task now is to transfer these forces from the outside of the thermal insulation to the structural wall with as little thermal bridges as possible.

State of the art:

In most cases, metal structural components penetrate the thermal insulation and thus represent significant thermal bridges. With careful planning, plywood parts are often doweled to a wall, to which steel structures can then be screwed. This procedure reduces the thermal bridge effect, but is complex and usually not system-compliant.

Solution to the task:

The invention is therefore based on the object of creating a construction element (power anchor) via which, suitable for a respective thermal insulation system, all static requirements that, for example, have to be introduced into the wall from a canopy, can be transferred in a way that minimizes thermal bridges.

The object is achieved according to the invention in that in a structural element (power anchor) that is integrated into a respective thermal insulation system, both compressive, tensile and transverse forces are introduced from the outside of the wall into the structural wall in a way that minimizes thermal bridges. In this process, compressive forces are diverted via a rod made of pressure-resistant thermal insulation material. The tensile and transverse forces are directed into the wall via tension anchors made of stainless steel wire or other tensile materials such as glass or carbon thread. All of the necessary structural parts can now be attached to a threaded rod that is thermally separated from the metal tension anchors.

The invention is explained in more detail below with the aid of drawings. The drawing shows (Fig. 1) a power anchor in a thermally insulated wall. (Fig. 2) the same power anchor in section and (Fig. 3) a variant of a power anchor in section.

Fig. 1 shows an isometric view of a thermally insulated wall. The force anchor is marked with 1, the compression rod, which is integrated in the force anchor and consists of pressure-resistant thermal insulation material, is marked with 2. In this version, the tension anchors 3 take on tensile and transverse forces. To transmit the force, the ends 3a can be embedded in the wall 10 and fastened with a reactive adhesive, for example, or they can be designed as a loop 3b and attached to the wall with conventional fastening elements such as dowels. The threaded rod 4 is the external fastening element to which the required components are screwed. The threaded rod 4 is screwed into the threaded plate 5, which transmits the tensile and compressive forces. The threaded rod 4 and the threaded plate 5 are thermally separated from the tension anchors 3. The distance at which the tension anchors are anchored in the wall is selected depending on the magnitude of the transverse forces that need to be diverted. All structural elements of the force anchor are cast into a thermal insulation block 8. This thermal insulation block 8 is attached to the wall 10 together with the insulation panels 9.

Fig. 2 shows the force anchor in section. Due to the widely spaced fastening of the tension anchors 3 in the wall, this force anchor can absorb high transverse forces. In this illustration, the ends of the tension anchors can be anchored in the wall 10 with a reactive adhesive, for example.

Fig. 3 shows a variant of the force anchor, which is designated la. This force anchor corresponds to the force anchor in Fig. 1 and Fig. la. It is primarily intended for subsequent installation. At the base of this force anchor, a threaded rod 7 is attached, which is firmly connected to a pressure distribution plate 6. The tension wires 3 are also connected to this plate. As an alternative to the metal tension wires, a tensile reinforcement made of other tear-resistant materials such as glass or carbon fiber can also be used. A piece of the thermal insulation 9 is removed using a core drill. A hole 10a is made in the wall 10 in the middle of this hole in the thermal insulation. An injection compound 11 can then be introduced into this hole 10a. The force anchor la with the threaded rod 7 is then pushed into the hole, the injection compound bonds with the threaded rod, thus creating a force-locking connection ^between wall 10 and threaded rod 4.

Claims (7)

Expectations 1. Power anchor for thermal insulation constructions, characterized in that it consists of a rod made of pressure-resistant thermal amine material (2) and tension anchors (3) made of metal or other tear-resistant materials. 2. Power anchor according to claim 1, characterized in that a threaded rod (4) and a threaded plate (5) are integrated into the pressure-resistant thermal insulation material (2). 3. Power anchor according to claim 1, characterized in that tie rods (3), if they are made of metal, are thermally separated from one another by the threaded rod (4) with threaded plate (5). 4. Power anchor according to claim 1, characterized in that the tie anchors (3) are firmly anchored in the load-bearing wall (10). 5. Power anchor according to claim 1, characterized in that the tension anchors (3) are firmly anchored in the load-bearing wall (10) with a pressure distribution plate (8) and a threaded rod (7). 6. Power anchor according to claim 1, characterized in that any constructions can be attached to the threaded rod (4). 7. Crane tanker according to claim 1, characterized in that it is used both as an integral component of a thermal insulation system or can also be used for subsequent installation in a thermally insulated wall. Kassel, 09.05.1998 ■ling