Thermo floors can be used in almost all areas, from new constructions up to complete renovations of old objects. On thermofloors all floor coverings, suitable for underfloorheating, can be used:
At the present time, out of economic and ecological view, rooms are heated and cooled via activated surfaces and the room climate is regulated through pleasant radiant heat. The big advantage of thermo floor shows in the costs, because the larger the heated surface, the less energy has to be used.
Consequently, the costs of heating and cooling are reduced and, in addition, the environment is less burdened and with the help of calcium sulfate plates an optimal heat transport is guaranteed.
The pipes for the underfloor heating are set in a special milling in the panel and then closed with putty.
The used pipes are made of highly cross-linked polyethylene, which clearly surpasses the oxygen-tightness of standard requirements.
In the substructure pedestals are used, which can be adjusted exactly in height.
The hollow floor with prefabricated millings for the heating medium is built up first, according to the installation plan.
Subsequently the plastic tube is clipped into the holding grooves.
Cutouts can be prefabricated (for example for electric floor tanks).
After the pipes have been tested for leaks, the pipes are embedded with a special filling compound.
After solidification, the supernatant is pushed plane with the surface, thus producing a flat surface of high quality.
After functional heating the cover can be laid.
Heating operation | pipe grid 100 mm | pipe grid 150 mm |
| Heat flux density qG according to | ||
| DIN EN 1264-2 (without covering, R = 0,00 m² K / W) | 77 W/m² | 60 W/m² |
| at standard heating medium excess temperature ΔθH | 11,69 K | 12 K |
| Heat flow density qG according to | ||
| DIN EN 1264-2 | 89 W/m² | 78 W/m² |
| at standard heating medium excess temperature ΔθH | 25,89 K | 29 K |
Cooling mode | pipe grid 100 mm | pipe grid 150 mm |
| Specific cooling capacity q according to | ||
| DIN EN 1264-5 3 | 38,2 W/m² | 28,7 W/m² |
| Coolant temperature ΔθH | 8 K | 8 K |
Panel | |
| System weight | approx. 64 kg/m² |
| Base layer | gypsum fiber board 40 mm |
| Support plate | 600 x 600 mm with trapezoidal tooth profile and heating tube groove |
| Diffusion barrier | underside aluminum coating / for higher loads underside steel sheet |
| System weight | approx. 64 kg/m² |
| Laying distance | 150 mm, 100 mm, edge zones possible |
| Heating pipe | polyethylene Alternative: Roth multi-layer composite tube Alu-Laserflex 16 x 2 mm oxygen-tight according to DIN 4726 Multilayer composite pipe possible |
| Fillers | Special filling compound, castor-proof, temperature-resistant |
Subconstruction | |
| Pedestal grid | 600 x 600 mm |
| Reinforcement border area | None, grid bar or other reinforcement measure |
| Pedestal material | steel, galvanized |
Load Values | |
| Point load: | 3.000 / 4.000 / 5.000 (15,000 N in connection with 30mm stone pavement) |
| Element class accord. to DIN EN 13213 | load class 3 / 4 / 5 / 6 |
| Breaking load | ≥ 6000/8000/10 000/30 000 N |
Cover | |
| Material: | textile and elastic floor coverings, parquet, natural stone, artificial stone, ceramics |
| Functional heating: | from 36 hours after casting for 48 hours |
| The maturity of the floor structure | immediately after the functional heating and cooling |
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