FI12069U1 - Ventilated floor structure - Google Patents

Abstract

1. Ventilated floor structure (1) on top of a concrete bottom plate (2), characterized in that the ventilated floor structure (1) comprises five parts; a leveling molding (3) cast on top of the bottom plate (2), a disc-shaped insulating layer (4) with a uniform surface placed on top of the smoothing molding (3), insulating sheets (5), provided with grooves (7) on the underside, which are placed on top of the disc-shaped insulating layer with a smooth surface, tubes (8) connecting the grooves (7) on the underside of the insulation boards and a cladding layer (6) at the top. In addition, the protection requirements 2-3.

Description

VENTILATED FLOOR STRUCTURE TECHNICAL FIELD

The present invention relates to a ventilated floor structure on a concrete slab comprising a screed, a dielectric layer and a surface layer mounted on a concrete slab structure. The structure is made up of a screeding compound for an uneven concrete slab, a flat-plate insulator, a grooved-plate insulator forming air ducts between the insulators, pipes connecting the groove and a coating material forming the surface of the inner floor.

BACKGROUND OF THE INVENTION

Substrate insulating structures on concrete slabs are known in the prior art, particularly in the case of fake shingle foundations built in the 1960s and 1990s. In old concrete floor slabs containing concrete slabs, insulation with a wooden frame has often been used as insulation. When repairing the false tile foundation structures, the concrete slab structure is generally provided with an insulating layer using about 100 mm to 150 mm eps or xps insulation, and a concrete slab generally forming about 70 mm to 100 mm is cast over the insulation. Forming a concrete slab always also requires reinforcement and generally also underfloor heating, because the concrete structure with the aforementioned insulation strengths feels cold in the feet. Renovating such a structure is time consuming, cumbersome and expensive. Also, moisture and radon gas that may rise from the concrete slab is not controlled by this technique. Also, the insulation strength must be kept low to prevent the concrete floor structures from rising above the previous level of the inner floor. Also, the humidity and temperature performance of the lower parts of the floor is lower when the amount of insulation is low.

PURPOSE OF THE INVENTION

It is an object of the present invention to provide a simple and functional floor structure which is easy to install on a concrete slab structure compared to the prior art. It is also intended to avoid the use of heavy concrete as a surface structure and the resulting reinforcement and casting work. It is also intended to provide ventilation inside the floor structure. In particular, the invention seeks to solve how the humidity, which is usually carried as water vapor from below, and the radon gas that may rise from the ground can be controlled in a controlled manner out of the floor structure. Another object of the invention is to make the installation of a floor structure easier and faster than before.

The insulation of the floor is also improved by the present invention when the thick concrete floor casting is eliminated and replaced by an insulating material. Due to the structure below, expensive floor heating may not be necessary, since the floor structure consists mainly of insulating material and usually of interior or backing materials containing wood or cork and thus does not feel cold. It is also an object of the invention to keep the baseplate and the plinth structures as dry as possible so that they do not freeze when frozen and thereby crack.

SUMMARY OF THE INVENTION

The ventilated floor structure according to the invention is characterized in that the floor structure comprises five parts; leveling mold, a uniformly well-vapor-permeable insulating layer having a sheet size of e.g. 120 mm x 1000 mm x 1200 mm, followed by a dense structured underside insulating sheet placed on top of the first insulation layer, e.g. 50 mm x 600 mm x 2400 mm and interconnecting, e.g. 10 cm pipes and another Fifth part, ie the cladding material of the inner floor, which forms the sheet-forming inner floor surface on the insulation. The floor structure is formed by gluing the first flat surface layer of insulation to the leveled surface and sealing it with its foam seams, for example. Next, the hot wire cutter is embedded in any pipe drawings on the surface of the first insulating layer and subsequently filled with the grooves caused by the piping, for example with glue foam. The grooved insulating material at its underside is then glued to the surface of the first installed insulating layer, thereby forming a desired ventilation duct between the insulators, to which the supply and exhaust ducts are connected. Next, the surface floor can be installed directly on top of the insulation layers.

The usefulness of the ventilated floor structure according to the invention is based on many things. The present invention can be used, for example, in renovation construction, to prevent moisture rising from the concrete slab structure in various ways from entering the surface layers of the floor structure. The invention can also be used in new construction to ensure the moisture-proof function of the subfloor. The invention also allows controlled release of radon gas. By utilizing the ventilated floor structure of the present invention in repair and construction, it is possible to reduce the cost of repair and obtain a ventilated floor structure that is well-functional in terms of humidity and temperature. Installed directly on high load-bearing insulation, the floor cladding material also reduces working time and is inexpensive and quick to install. The insulating structure according to the invention can also be formed in various ways on the surface to which the cables or pipes required for underfloor heating can be connected. The lower grooved insulation material can also be used separately, for example on problem floors, to remove vapors and gases rising from the floor to the room air.

One skilled in the art will appreciate that the dimensions, materials, and groove shapes are indicative and may vary within the scope of the invention.

LIST OF FIGURES

Embodiments of the invention will now be described with reference to the figure wherein

Figure 1 shows a preferred embodiment of the ventilated floor structure according to the invention, in which the insulating materials and the interior surface cladding material are placed on a leveling molding. At the bottom of the picture is a so-called junk concrete slab.

Fig. 2 shows, by way of example, four separate insulating plates which are still separated from one another and the pipes connecting the air ducts between them, as well as the ventilation air inlet and outlet pipes. The figure also shows by way of arrow the direction of air flow in these four cross-grooved insulating plates and inlet and outlet pipes.

DETAILED DESCRIPTION OF THE INVENTION

The ventilated floor structure 1 comprises five parts; a leveling mold 3, a flat insulating layer 4, a grooved insulating layer 5 of insulating material, a grooved 7 insulating layer 5 interconnecting pipes 8 and a sheet-like surface cladding layer 6.

The present ventilated floor structure 1 is fabricated from below upwards; self-leveling screed casting, insulating layer 4 e.g. 120 mm x 1000 mm x 1200 mm, next underside, e.g. 20 mm, cross-ribbed 7 insulating sheets 5, e.g. 50 mm x 600 mm x 2400 mm, tubes 8, e.g. 16 mm and length 100 mm and a tongue-and-groove surface-forming layer 6 of, for example, 15 mm x 300 mm x 1200 mm.

Figure 1 is a cross-sectional view of a ventilated floor structure 1 according to the invention. The upper surface of the base plate 2 of the Luna-Luna base is leveled by a self-leveling screed 3 having a thickness of approximately 2 cm, for example a 12 cm thick water-permeable insulating layer 4 is placed over the insulating layer 4 having a groove 7 an insulating plate 5 having a thickness of 5 cm, for example a surface cladding layer 6 having a thickness of 15 mm is placed thereon. The insulating layer 4 is also formed here with a hot-wire cutter for installation needs 10.

Fig. 2 is a top plan view of four pieces of mutually spaced slabs 7 of insulating panels 5 provided with a cross slit 7. There are air ducts connecting 16 mm diameter and 10 cm air ducts between the insulating panels 5. The figure also shows the insulating board 5 the connected supply air duct 11 and the exhaust air duct 9. The arrows 12 indicate the movement of the air in the cross groove 7 when the pipes 8 are arranged as shown.

It will be obvious to one skilled in the art that the above dimensions, materials, hole locations and groove shapes are indicative and may vary within the scope of the invention.

On the cleaned base slab 2 of the present ventilated floor structure 1, a smoothing casting 3 of the required thickness is carried out, for example, using a self-leveling casting compound. Insulating boards 4 are glued on the leveling molding 3, the seams of the insulating boards 4 are glued and sealed together with, for example, eps glue foam. Thereafter, the hot plate cutter 10 forms the necessary pipe grooves 10 in the insulating plate 4, for example for a central vacuum cleaner and for electric, heating and water pipes. The pipe grooves 10 are filled with eps adhesive foam so that the pipe grooves 10 will not be disturbed by air passage on the floor.

Next, the cross-grooved insulating board 5 is attached, for example, with adhesive to the surface of the insulating boards 4, leaving a space of about 1 cm between the insulating boards 5 at the sides and ends where the pipes 8 are still visible. When installing the insulating panels 5, the ducts connecting the air ducts 8 are placed in the grooves 7 so that they form a uniformly continuous and pre-planned ventilation duct. Ventilation ducts must always be designed on a case-by-case basis to provide the necessary ventilation. The transverse grooves 7 can be connected by pipes 8 in the longitudinal and width directions as needed so that the ventilation covers as much as possible the entire floor. The one cm space between the insulating boards 5 is next filled with eps adhesive foam, thereby closing the grooves 7 which are not used. The supply air duct 11 and the exhaust air duct 9 are intended to be installed in places where the ducts installed in the insulating panels 5 do not interfere with the comfort of living. Indoor air is always used as supply air and exhaust air is mechanically exhausted. Supply air ducts 11 are always fitted with air filters to keep the ventilation duct clean.

The scope of the invention is defined by the following claims. It will be apparent to one skilled in the art that the details of various aspects of the invention may vary within the overall inventive concept, depending on embodiments of the invention.

Claims (3)

PROTECTION REQUIREMENTS 1. Ventilerad golvkonstruktion (1) ovanpå en bottenplatta (2) av betong, kännetecknad av att den ventilerade golvkonstruktionen (1) omfattar fem partier; en utj amning sgjutning (3) som gjuts ovanpå bottenplattan (2) that skivformigt isoleringsskikt (4) med jämn yta som placeras ovanpå utjämningsgjutningen (3), isoleringsskivor (5), försedda med spår (7) på undersasan, som. skivformiga isoleringsskiktet med jämn yta, rör (8) som kopplar samman spåren (7) på undersidan av isoleringsskivoma samt et beklädnadsskikt (6) from the overpass. Ventilated floor structure (1) on a concrete base slab (2), characterized in that said ventilated floor structure (1) comprises five parts; over the cast on the base plate (2) tasoitusvalun (3), tasoitusvalun (3), set flush plate-shaped insulating layer (4), flush the plate-like imposed on the insulating layer underneath the grooved (7) the insulating plates (5), the insulation plates the underside of the corrugations (7), the connecting tubes (8) , as well as the top pin lining layer (6). 2. Ventilerad golvkonstruktion (1) enligt skyddskrav 1, kännetecknad av att de spår (7) som rören (8) kopplar samman bildar ett ventilationskanalsystem. Ventilated floor structure (1) according to claim 1, characterized in that the grooves (7) connected to each other by the pipes (8) form a ventilation duct. Ventilated floor structure (1) according to the protection claim 1 or 2, characterized in that the groove (7) is connected to the mechanical ventilation by the exhaust air duct (9) and the supply air duct (11). SKYDDSKRAV 3. Ventilators golvkonstruktion (1) enligt skyddskrav 1 eller 2, tilt decknad av att spåren (7) har kopplats till en fläktventilation med hjälp av et frånluftsrör (9) och ett tilluftsrör (11).