SE500465C2 - Intermediate flooring that can be used to heat living space above the floor and the process of making the flooring - Google Patents

Abstract

The invention relates to an intermediate floor structure comprising a plate floor structure (10) having spaced apart embedded stiffening means (11), and a method in such an intermediate floor structure. A layer made of heat insulating material is arranged above said plate floor structure (10), and above said layer made of heat insulating material there are arranged conduit means (12) for distributing a heat medium. A curing filling material is arranged for embedding said conduit means (12). In the method according to the invention a heat insulating layer is arranged above said plate floor structure (10) and a heat carrying medium is distributed in said intermediate floor structure above said heat insulating layer for emitting heat to and storing heat in said intermediate floor structure. Emission of heat from said intermediate floor structure is directed upwardly from said heat insulating layer towards the space above said intermediate floor structure.

Description

'-. | . FIG. 2 is a cross-sectional view of an alternative embodiment of the intermediate floor according to the present invention, FIG. 3 is a sectional view taken along line 3-3 of FIG. 5 of an embodiment of the intermediate floor layer according to the invention, FIG. 4 shows an embodiment with a heating unit for heating the intermediate floor and FIG. 5 is a top plan view of an intermediate floor according to the inventor.

In the embodiment according to FIG. 1, a concrete slab 10 has been applied to existing walls of a house under construction. The walls can consist of outer walls and / or inner walls. The flat support layer 10 is provided with reinforcing elements in the form of truss beams 11, which are partly embedded in the flat support layer. The truss beams 11 are made of two wire elements bent in a zigzag shape, which are arranged so that the beam has a triangular cross-section and these connecting straight wire elements. FIG. 3 shows the reinforcement beams in cross section.

The flat support layer described above occurs today as a commercial product. During normal use of this flat support layer, after the flat support layer has been arranged on existing walls, concrete is filled with the flat support layer constituting the bottom of a mold. The mold is also provided with side walls, for example in the form of wooden beams or beams 16 (see FIG. 2). When the concrete has subsequently solidified and the desired drying has been achieved, a floor covering of the desired type can be applied to the top of the concrete slab.

In contrast to this conventional use of flat support layers 10, the following measures are taken in accordance with the present invention. Before concrete is filled, a heat-insulating layer is applied to the top of the slab layer 10.

Preferably, the heat-insulating layer consists of insulating plates, for example in the form of cellular plastic. Due to the low density of the cellular plastic in relation to concrete, saving of concrete is achieved in the production of the intermediate floor layer and reduction of the weight of the intermediate floor layer. The cellular plastic also has good heat-insulating properties, whereby the desired direct effect can be achieved for the heat dissipation that takes place from the intermediate floor. The thickness of the foam sheet is selected, partly with regard to the desired heat-insulating ability and partly with regard to the weight loss to be achieved. The thickness of the foam sheet also depends on the dimensions of the tubes 12, which are applied to the top of the plates. The total height of the heat insulating layer and the pipes 12 must be less than the total height of the intermediate floor.

The pipes 12 are arranged in loops on the foam sheets, or in another way above the plate support layer 10. The path or paths in which the pipes 12 are laid must give the desired distribution of the heat supplied in the pipes (see FIG. 5).

Thereafter, further wall sections can be erected on top of the mezzanine floor, or rather on the side walls of the mold constituting the wooden rules 15 or the beams 16. The further wall sections can optionally be supported by means of inclined beams or the like, which are attached to the beams ll. By allowing additional wall elements to be erected and additional intermediate floors to be arranged thereon, subsequent casting of the intermediate floor can take place in a more protected environment, which is most closely regarded as an indoor environment. In this case, the casting takes place by pumping concrete in the form delimited by the flat base layer as the bottom and by wooden beams 15 or beams 16 as side walls. The concrete then flows out into the space on top of the heat-insulating layer and also into the interior of the beams 11 and under the additional wall sections erected on top of the floor.

FIG. 2 shows an alternative embodiment to that in FIG. 1, the latter figure showing an embodiment with horizontal U-beams with the stacks facing the intermediate floor. The embodiment otherwise corresponds to the embodiment according to FIG. 1.

From FIG. 3 shows how the beams 11 are arranged at a mutual distance from each other and partially embedded in the plate support layer 10. Between the beams 11, the plates 13 of cellular plastic are arranged. Several elongate slab layers are connected along the long sides to form a continuous bottom to the mezzanine floor. The connection of the flat support layers can take place, for example, by means of plates, which are screwed into the flat support layers 10. Preferably, the joining of several flat support layers takes place at the factory, so that flat support layers in the right dimensions can be mounted directly on erected walls at the construction site.

The space between the zigzag-shaped sides of the beams 11 is used in the preferred embodiment for receiving pipelines 17, which can be used for installation of electrical pipes or plumbing pipes.

The installation can take place before casting or after casting. In an embodiment not shown, the pipelines 17 are also drawn at right angles to that in FIG. 3 showed the extent.

This enables further installation after the casting of the mezzanine floor as well as changes to the installation afterwards.

FIG. 4 shows an embodiment of a heating unit 14, which is arranged in the intermediate floor and which is connected to the pipes 12 in a closed circulation system.

Suitably the dimensions of the heating unit 14 are such that it can be completely embedded in the intermediate floor, ie its height should not exceed the total height of the intermediate floor.

The heater 14 comprises a heating element and some form of circulation pump. Air is heated by the heating element and then circulated in the closed system by means of the circulation pump. Because the system is closed, the risk of polluted air being taken into the intermediate floor and there can cause mold infestation or the like is eliminated.

From FIG. 5 shows how the pipelines 12 can be arranged in order to achieve the desired distribution of heat.

Suitably several loops are made, so that a relatively even temperature can be maintained throughout the loop.

The loops can be made with thicker or thinner pipes to further equalize the temperature release from the air in the pipes to the concrete.

Because the upper floor of the mezzanine floor is also provided with a heat-insulating layer, for example in the form of a conventional floor covering or similar, some heat storage takes place in the concrete of the mezzanine floor. It is also possible with different thicknesses of the thermal insulation layer on the upper side of the mezzanine floor to achieve non-homogeneous heat dissipation from the concrete, if desired. The temperature of the circulating air, the thickness of the heat-insulating layer on the top of the concrete slab, the thickness of the heat-insulating layer 13 and the desired temperature in the space above the mezzanine floor are factors that are weighed together to achieve the desired indoor temperature and otherwise desirable and controllable conditions in the living space.

As can be seen from both FIG. 1 and FIG. 2, the intermediate floor along its side edges is provided with an edge element 18. Preferably, this consists of cellular plastic, which has good heat-insulating and moisture-barrier properties.

This prevents a cold bridge from arising between the heated mezzanine floor and the external environment.

Within the scope of the invention defined in the independent claims, many of the above-described components of the intermediate floor can be replaced by components with corresponding properties. For example, the beams 11 can be replaced by other stiffening means by means of which stiffening of the intermediate floor can be achieved. The heat-insulating layer 13 can be constituted by other materials with heat-insulating properties, and it is also possible in connection with the production of the flat support layer to integrate the insulating layer 13 therein, so that the flat support layer and the insulating layer form a unit. The flat support layer 10 is suitably made of concrete with a finished sub-surface, but other embodiments are also conceivable. For example, a special suspended ceiling panel can be integrated with the flat support layer.

The heat-insulating layer functions not only as thermal insulation and for the direction of heat dissipation also as a savings body, whereby the total weight of the intermediate floor is reduced.

Claims (5)

(fl (ff) (_). ft »(U L) 1 PATENTKRAV Intermediate floor layer, comprising plate support layer (10) with spaced-apart stiffening means (11), wherein portions of the stiffening means (11) are arranged projecting from the plate support layer (10), characterized in that a layer of heat-insulating material is arranged on top of the plate support layer. (10), that above the layer of heat-insulating material are arranged pipes (12) for the flow of gas medium in a closed system and that a hardening filling material is arranged for embedding the pipes (12) and the projecting portions of the stiffening means (11) and for receiving of heat from the gas medium flowing through the pipes and for directed dissipation of heat to a space existing above the mezzanine floor. Intermediate floor according to claim 1, characterized in that the layer of heat-insulating material consists of plates (13), which abut against the slab support layer (10), and that the pipes (12) abut against the slabs (13). Intermediate floor according to claim 2, characterized in that the plates (13) are made of cellular plastic. Intermediate floor according to claim 1, characterized in that an air heating unit (14) is arranged embedded in the intermediate floor layer to heat and circulate the gas medium in the pipes (12). A method of intermediate floor layer, wherein the intermediate floor layer comprises a flat support layer (10) with spaced-apart stiffening means (11), parts of which project from the flat support layer (10), characterized in that a heat-insulating layer is applied to the top of the flat support layer (10). and that heating and heating gas is caused to flow through a heat accumulating filling material of the intermediate floor above the heat insulating layer for dissipating heat to and storing heat in the intermediate floor, the heated gas is circulated in a closed system, and the heat dissipation from the intermediate floor is directed upwards from the heat-insulating layer.