DE4423137A1 - Energy saving outer wall of building - Google Patents

Abstract

Supporting structure of a building has an outer wall consisting of a rendered layer (10) and a solar energy absorber system installed between the rendered layer and the structure (2). At least one metal or polypropylene capillary tube (5) is provided on mats (4) positioned on a thermal insulation layer (4) provided over the structure, for flow of a heat transport fluid. Pref. the capillary tube consists of two parts connected in parallel with a spacing of 10-15 mm. The tubing is pref. embedded in a reinforcing material (9) contg. C and/or polyacrylnitrile fibres with mineral and/or organic filler.

Description

The invention relates to an outer wall of a building with a Plaster layer provided outside of its supporting structure.

The known building exterior walls of this type have, provided that only have masonry that on the outside Plaster layer carries a relatively low thermal insulation. It is therefore common between the outside of the masonry and to arrange the plaster layer with a thermal barrier coating. In order to it is possible to design the outer walls of buildings that there is a significant saving in the building for the Heat generation required primary energy can be achieved.

They also serve to save primary energy in buildings solar collectors arranged on the roof, but expensive are, often not for retrofitting existing buildings are suitable and the architectural appearance of the Change building significantly.

The invention is based, so far for the task Possible energy saving in buildings expanding. An outer wall of the building solves this task  with the features of claim 1.

A between the plaster layer and the supporting structure of the Building exterior wall arranged solar energy absorber system can a noteworthy part of those striking the plaster layer and absorb into this penetrating solar energy. The heated transport liquid can be anywhere where a There is a need for heat, at least some of its heat energy, for example via a heat exchanger. The However, there are particular advantages of the solution according to the invention in that the solar energy absorber system is inconspicuous, namely invisible, can be integrated into the building skin, so that the architectural design options of the facade not be restricted that there is a retrofit at The buildings can easily be large Areas are available over which the solar energy absorber system can extend that except a pump or possibly no moving parts for one or more valves are required that good controllability is given and a Overheating of the building is impossible because of the sun Energy only needs to be used when it is needed and that free cooling is also possible in summer.

The solution according to the invention is particularly advantageous if if the solar energy absorber system between the plaster layer and one on the outside of the supporting structure of the wall applied thermal insulation system is arranged. This thermal insulation systems insulate the heat dissipation from the plaster layer into the supporting structure of the wall, for example that Masonry, and the better their insulating ability is. As the trend towards thicker thermal insulation layers goes, in order to reduce the need for heating energy in the building, the plaster layer reaches relatively high temperatures. That directly is under the plaster layer solar energy absorber system therefore exposed to comparatively high temperatures, leading to correspondingly high temperatures of the heat transfer liquid leads, resulting in the uses of the absorbed  Thermal energy can still be significantly improved. Come in addition, that the thermal energy absorber system in that it has a considerable proportion of those penetrating the plaster layer Can absorb energy, greatly increased, the stability and the Bonding the plaster layer with the thermal insulation layer Can reliably prevent temperatures of the plaster layer.

In principle it would be possible to use the pipeline or pipelines of the solar energy absorber system directly on the load-bearing Structure or, if a thermal barrier coating is provided, on to determine this. In a preferred embodiment however, the piping on one side of a mat fixed with the outside of the supporting structure or the thermal insulation layer is connected. As a result, the Verle tion considerably simplified, especially since such a mat with the on her specified pipes as a prefabricated component ment can be executed.

Pipes made of metal or are particularly advantageous Plastic, because such pipes or hoses appear tendency thermal expansion and especially shock-like tempera Endure door changes without damage. A particularly suitable Plastic is polypropylene, which also weld well lets so that connecting different pieces of piping is possible without difficulty.

To keep the thickness of the solar energy absorber system as small as possible to be able to hold, is preferably an inner diameter of Pipelines of at most 5 mm, preferably less than 2 mm. So it is a so-called capillary tube re. These usually require a parallel connection of one larger number of pipe sections, all of distribution and Bus lines are connected, which is essential have a larger inner diameter.

As a rule, a distance between immediately adjacent sections of the pipeline or pipelines in the area  from 5 mm to 100 mm, preferably in the range from 10 mm to 15 mm, for good heat absorption over the entire surface to lead.

In a preferred embodiment, the pipes are at least partially embedded in a reinforcing compound, which the expansion of the pipelines when they are heated compensates so far that the plaster layer remains free of cracks and their weather conditions, which are particularly important for the thermal insulation layer maintains stability.

The plaster layer can be applied to this reinforcement his. But you can also go through the piping part of the reinforcing compound covering the outside.

The reinforcing compound is preferably made of carbon fibers and / or Reinforced polyacrylonitrile fibers.

The reinforcing compound consists in a preferred embodiment example from an inorganic or organic binder or a mixture of such binders. Furthermore can the reinforcement mass mineral and / or organic filler fe included. It can also be beneficial if the armie tion mass contains a hydrophobizing substance.

In the following the invention is based on one in the drawing illustrated embodiment explained in detail. It demonstrate

Fig. 1 is a schematic representation of a portion of the exporting approximately embodiment and various heat demand systems as well as their connection with the embodiment

Fig. 2 shows a section of the embodiment on a larger scale.

A vertical outer wall of a building, for example a residential house, designated as a whole by 1 , has a supporting structure 2 formed by masonry. This masonry consists for example of hollow perforated bricks or sand-lime brick with a thickness of 0.24 m. The inner surface is plastered with a layer of lime gypsum mortar 3 to a thickness of 0.015 m. On the outside of the supporting structure 2 , a thermal insulation layer 4 consisting of stone lamellae is fixed, the thickness of which is 0.08 m. On the outside of the heat-insulating layer 4 facing away from the load-bearing structure 2, mats are attached to one another, on the side of which the heat-insulating layer 4 is turned away, capillary tubes 5 are fixed. The capillary tubes are made of polypropylene and have an inner diameter of 1.7 mm. All or at least part of the capillary tubes 5 fixed to each mat are connected in parallel. Your beginning is connected to a distribution line 6 , its end to a manifold 7 , which are also made of poly propylene, which is why a connection is possible by welding. The diameter of the distribution lines 6 and collecting lines 7 is 16 mm in the exemplary embodiment. These lines are ver in recesses 8 of the thermal insulation layer 4 and passed at a suitable point through the supporting structure 2 .

On the outside of the mat carrying the capillary tubes 5 , a reinforcing compound 9 is applied, the part of the reinforcing tubes 5 covering the outside forming a plaster layer 10 . The reinforcing compound 9 can accommodate large expansions of the capillary tubes 5 without cracks occurring in the plaster layer 10 or losing their weather resistance, which is particularly important for the thermal insulation layer 4 . Even sudden changes in temperature or a very large temperature drop do not endanger the reinforcing compound 9 and therefore not the plaster layer 10 .

Carbon fibers are provided as reinforcement. But also  Polyacrylonitrile fiber or a mixture of both fibers species is beneficial.

The binding agent of the reinforcing compound is compatible with cement che polymer dispersion. But there are also other organic ones as well as inorganic substances in question. Art is advantageous dispersions based on acrylate and styrene acrylate Vinyl acetate copolymer base, vinyl acetate polymer base, or on a similar basis, as well as mixtures of such substances fen. As inorganic binders are water glass, hydraulic cements or the like, optionally in mixtures with the aforementioned polymers, advantageous.

The reinforcing compound 9 is mixed with a hydrophobic additive beige. Such additives include, in particular, stearates, silicon oxanes, silicone resins or the like. It is also advantageous to add to the binder of mineral or organic fillers. In particular, quartz, calcite, mica, talc and pumice come into consideration as mineral fillers, preferably in a grain size up to approx. 6 mm in diameter. In the exemplary embodiment, the plaster layer 6 has a grain size between 2 and 6 mm.

All manifolds 7 are connected to a pump 11 which can be driven by an electric motor, from the pressure side of which, in the exemplary embodiment, lines to a heat exchanger 12 in the cold water inflow for hot water heating, to a low-temperature heating system 13 with a heat pump, for example for heating the water in a swimming pool is seen to run to a low-temperature surface heating system 14 , for example in the form of underfloor heating, and to a pumping system 15 on the north side of the housing. The return lines are connected to the distribution lines 6 . A valve 23 is provided in each of these return lines in order to be able to switch the aforementioned systems 12 to 15 on and off as required.

The capillary tubes 5 , the distribution lines 6 , the collecting lines 7 and the systems 12 to 15 are filled with a liquid, in particular with an antifreezing water.

At least one temperature sensor 16 supplies a controller 17 with the value of the temperature prevailing in the reinforcing compound 9 . Of course, several temperature sensors can be distributed over the facade in the reinforcing compound 9 or on its boundary surface.

In the exemplary embodiment, a second temperature sensor 18 is arranged in the heat exchanger 12 . Additional temperature sensors could be installed in the low temperature heating system 13 or the underfloor heating.

The controller 17 compares the temperatures in the heat exchanger 12 and the reinforcing compound 9 and switches on the pump 11 when the temperature in the reinforcing compound 9 exceeds that in the heat exchanger 12 . Only if the energy supplied by the solar energy absorber is not sufficient to bring the hot water heated in the heat exchanger 12 to the desired temperature, a heating system 19 provided in the heat exchanger 12 , which is fed, for example, from a heating boiler, is switched on.

The energy supplied by the solar energy absorber can also be supplied to the low-temperature heating system 13 and / or the low-temperature surface heating system 14 . For this, only the associated valves need to be opened.

In addition, it is possible in the exemplary embodiment to pump the water flowing through the capillary tubes 5 through a tube system 20 which is laid between the masonry 21 and a thermal insulation layer 22 on the north side of the building. The water can be cooled as it passes through the pipe system 20 and can therefore be returned to the capillary pipes 5 in the cooled state, as a result of which the plaster layer 10 can be cooled.

The solar energy absorber system can also be used for cooling purposes. If, for example, at night the temperature of the material containing the capillary tubes 5 , i.e. the reinforcing material 9 and / or the plaster layer, drops to a value which is lower than the interior temperature, the water cooling in the capillary tubes 5 can be cooled by cooling systems, in the exemplary embodiment by the low-temperature heating system 13 , the low-temperature surface heating system 14 and / or the pipe system 20 are pumped.

Claims (16)

1. Building outer wall with a plaster layer provided on the outside of its supporting structure, characterized in that between the plaster layer ( 10 ) and the supporting structure ( 2 ) a solar energy absorber system with at least one pipe ( 5 ) is arranged for the flow of a heat transfer liquid. 2. Wall according to claim 1, characterized in that the solar energy absorber system between the plaster layer ( 10 ) and on the outside of the supporting structure ( 2 ) applied thermal insulation layer ( 4 ) is arranged. 3. Wall according to claim 1 or 2, characterized in that the pipe ( 5 ) is fixed on one side of a mat which is connected to the outside of the supporting structure ( 2 ) or the thermal barrier coating ( 3 ). 4. Wall according to claim 3, characterized in that the mat with the pipe ( 5 ) fixed thereon is designed as a prefabricated component. 5. Wall according to one of claims 1 to 4, characterized in that the pipe ( 5 ) has at least two paral lel connected sections. 6. Wall according to one of claims 1 to 5, characterized in that the pipeline ( 5 ) made of metal or plastic, preferably polypropylene. 7. Wall according to claim 6, characterized in that the inner diameter of the pipeline ( 5 ) is less than 5 mm, preferably less than 2.0 mm. 8. Wall according to one of claims 1 to 7, characterized in that the distance between immediately adjacent sections of the pipeline ( 5 ) is in the range of 5 mm to 100 mm, preferably in the range of 10 mm to 15 mm. 9. Wall according to one of claims 1 to 8, characterized in that the pipeline ( 5 ) is at least partially embedded in a reinforcing compound ( 9 ). 10. Wall according to claim 9, characterized in that the plaster layer ( 10 ) is formed by the part of the reinforcing compound ( 9 ) covering the pipeline ( 5 ) towards the outside. 11. Wall according to claim 9 or 10, characterized in that the reinforcing compound ( 9 ) is reinforced with fibers, preferably carbon fiber and / or fibers made of polyacrylonitrile. 12. Wall according to one of claims 9 to 11, characterized in that the reinforcing mass ( 9 ) consists of an organic or inorganic binder or a mixture of such a binder. 13. Wall according to one of claims 9 to 12, characterized records that the reinforcing mass mineral and / or contains organic fillers. 14. Wall according to one of claims 9 to 13, characterized in that the reinforcing mass ( 9 ) contains at least one hydrophobizing substance. 15. Wall according to one of claims 12 to 14, characterized characterized in that at least part of the binder there is a cement-compatible polymer dispersion.   16. Wall according to one of claims 1 to 15, characterized in that little temperature sensor ( 16 ) is arranged in thermal contact with the pipe least.