A building envelope, in particular a wall, a floor, or a roof of a building with at least two shells spaced some distance apart from one another, which encloses an intermediate space, said space being essentially empty with the exception of weight-bearing and/or construction-engineering elements or being filled at least in sections with porous, open-celled material and sealed from the interior and exterior of the building, wherein controllable sealing means are provided for sealing the intermediate space from the interior and exterior and optionally separated building envelope sections from one other.

A building envelope, in particular a wall, a floor, or a roof of a building with at least two shells spaced some distance apart from one another, which encloses an intermediate space, said space being essentially empty with the exception of weight-bearing and/or construction-engineering elements or being filled at least in sections with porous, open-celled material and sealed from the interior and exterior of the building, wherein controllable sealing means are provided for sealing the intermediate space from the interior and exterior and optionally separated building envelope sections from one other.

A heat exchanger element has a heat-conducting body and a heat-transfer fluid pipe embedded in ducts having a channel-shaped locating section and two tabs connected flat to the heat-conducting body. To produce the heat exchanger element, foil strips are pressed into grooves so that they each form a section pressed into the grooves in a channel-like manner and laterally projecting tabs. A building panel has a heat exchanger element with a heat exchange surface, a cooling device and a collecting device, the cooling device being designed to cool the heat exchange surface in contact with the ambient air to a temperature below the dew point of the water vapour in the ambient air.

A concave-convex metal plate of a floor heating system according to the present disclosure includes repeatedly bent concave and convex portions to transmit a load from an upper portion of a finishing material to a floor slab. Because the concave-convex metal plate includes the repeatedly bent concave and convex portions, resistance to the load from the upper portion is significantly improved, thus functioning as a floor structural material that may sufficiently withstand the load, while transferring the load from the upper portion of the finishing material to the floor slab.

A building envelope, in particular a wall, a floor, or a roof of a building with at least two shells spaced some distance apart from one another, which encloses an intermediate space, said space being essentially empty with the exception of weight-bearing and/or construction-engineering elements or being filled at least in sections with porous, open-celled material and sealed from the interior and exterior of the building, wherein controllable sealing means are provided for sealing the intermediate space from the interior and exterior and optionally separated building envelope sections from one other.

Disclosed is a system comprising an envelope of a structure, heat pipes and fluid conduits, the envelope of the structure including at least two shells spaced apart from one another which enclose an intermediate space being sealed against an interior and exterior of the structure. First and second pipes, embedded in the exterior-facing and interior-facing shell of the structure, respectively, penetrate the envelope of the structure and together form the heat pipe for the circulation of a fluid to increase, hold or decrease heat transition through the envelope of the structure or affect heat transport into or out of the envelope of the structure.

A heat-conducting plate for fixing a pipe section to a holding surface of a heat exchanger, wherein the heat-conducting plate has perforations, in particular for acoustic reasons, wherein the perforations are not distributed uniformly over the entire surface of the heat-conducting plate.

Disclosed is a building envelope, in particular a building wall, floor, or roof, having at least two spaced-apart shells that enclose an intermediate space there between, the intermediate space being essentially empty except for weight-bearing and/or construction engineering elements or being filled in at least some sections with porous, open-cell material and being sealed from the exterior and interior of the building. A plurality of heat pipes which are connected to a heat collector on the shell facing the exterior and which end in the intermediate space is arranged in the intermediate space.

Methods, systems and devices for making a pedestrian, vehicular, or other surface resistant to frost, snow and ice by use of heat are disclosed. A composite base or deck element includes a recess to accommodate heating element. A thermal insulator has an upward facing layer of heat-conductive aluminum foil, above which sits the heating element. On top is a pedestrian, vehicular, or other exposed surface, for example a tactile warning surface.

Disclosed is a building envelope for a building wall, floor, or roof of a building, the building envelope comprising at least two shells spaced apart from one another that enclose an intermediate space there between, the intermediate space being sealed against the interior and the exterior of the building and being filled with structural weight-bearing and building-technology components, and at least in sections with a porous, open-celled 3D-pattern material. A plurality of heat pipes which are connected to a heat-collector element on the shell facing the exterior and the interior of the building and which end in the intermediate space are arranged in the intermediate space.