DE19525315A1 - Hollow flooring structure - Google Patents

Abstract

The hollow flooring structure, supported over the ground, has a hardening bonding agent system based on alpha hemihydrate, at least for the carrier boards (4). The bonding system has a sand additive, with cellulose and/or other inorganic fibres to give elasticity for the carrier boards (4). A layer, between the outer cladding (5) and carrier board (4), is of paper or plastics and esp. polyethylene.

Description

The invention relates to a raised floor, which arranged above a bare floor and with supporting bodies is provided, which stand on the raw floor and on-hook Carrier plates that have a continuous support Form a floor on which a covering can be applied.

Such a cavity floor is known as Support body has adjustable steel feet, one Support a large number of steel feet.

The steel feet are therefore considered to be adjustable in height Support body used because with them the overlying Carrier plates need to be leveled. This leveling the backing plate is necessary to ensure a secure support to reach.

The adjustable steel feet are z. B. from the bottom brought into prepared holes in the carrier plate. Then the steel feet are attached using their threads orders adjusted to the desired level so that one all steel feet touch the bare floor and none sudden subsidence after completion at Bela  stung occur and on the other hand the carrier plates waa are fairly aligned. The over the top of the Carrier plates projecting sections of the steel feet then removed. You can then click on the carrier flat coverings are applied.

This solution proves to be particularly disadvantageous that the steel feet can be used as a support body a large Represent cost factor and for their installation and Befe a lot of time is required on the carrier plates is such. The adjustment of the carrier plates on one same horizontal level is also with a lot of manual associated effort. In addition, the carrier plates are only partially accessible.

In addition, the entire cavity floor is through the use different materials in the case of a structural Changing the floor or room is extremely cost-intensive in an environmentally friendly reprocessing process degradable, as for sorting and separating the ver different material existing cavity floor components a lot of effort is required.

The invention has for its object a cavity floor, its components from a suitable recyclable building materials exist and are suitable are trained so that when installing the cavity floor reduced manual effort, especially time agile leveling of components of the cavity floor be avoided.

The object is achieved in that in the invention Cavity floor, the carrier plates and preferably the  Support body and the covering from a curable bandage consist of a system based on alpha hemihydrate. This binder system is preferably sand as Zu added impact.

It is advantageously placed on the carrier plates brought covering a screed layer, that of liquid screed will be produced.

The alpha hemihydrate is produced in one in a known manner technical recrystallization process from the at Flue gas desulfurization of domestic brown coal power plants known REA gypsum. The mixed with water finely ground alpha hemihydrate provides a liquid Binder system, which in addition to the essentially existing alpha hemihydrate still high quality additives may contain as well as sand.

The liquid binder system is used in molds for the Support body and carrier plates as well as for washers and the like initiated. That in the liquid binder system Alpha hemihydrate contained hardens during drying process, whereby in this process it depends on the addition is supported.

A solid product is then in the solid state, especially plates, bodies, washers or the like before.

By using the alpha hemihydrate be essential Lich more expensive building materials, such as B. steel and concrete saves. The products containing alpha hemihydrate such. B. Plates, bodies and washers are under the  structural conditions in rooms and buildings as well resilient as steel and concrete in the intended structural Use of the executed cavity bo according to the invention dens.

An improvement in the base plate structure and strength is achieved when the liquid, curable bandage by means of additional cellulose fibers or others organic and / or organic fibers are added. According to the invention, the elasticity of the carrier plates improved so that unevenness of the support floor can be compared, and thus an adjustment of the support body is not normally required.

Should there be major unevenness in the circulation in individual cases occur, it is possible to mark this by a "sub pour "the carrier plates in the area of the support body and / or by underlaying with the inventive sub to compensate for leg rings.

They are essential for the stability of a cavity floor Support body for the carrier plates, which not only as cuboid or cylindrical components are formed, but preferably through material-saving tapering conical, truncated cone-shaped or hyperboloid-shaped could be.

For special insulation purposes, in particular between the support floor and the applied screed layer Schrenzlage be misplaced. This situation can be considered environmentally friendly disposal from paper material consist. However, it is also conceivable the Schrenzlage made of plastic material, preferably of polyethylene film,  to manufacture. For sound and / or thermal insulation Mineral fiber mats according to DIN 18165 and hard foam panels according to DIN 18164 provided above the carrier plates will.

Depending on the shape of the carrier plates, the preferably quadra table or rectangular, they can be the respective support body, e.g. B. corner or edge lie on. A corresponding one is advantageous Stand grid to choose the support body on the bare floor Adjacent support plates have an equal share in the support the top surface of the respective support body to participate. It is essential that the required resilience of the Cavity floor is ensured.

The carrier plates according to the invention have a large size Elasticity so that the laying of a fiction according cavity floor with usual unevenness without additional leveling measures quickly and easily is possible because the backing plates are uneven can adjust. He also has a high stability, so that the cavity floor already when laying the beams plates can be walked on without restriction. By being able the cavity floor on the already laid support plates being able to walk there is a considerable simplification when laying the floor and applying the Self-leveling screed.

Another advantage of the invention is that the binder material used alpha hemihydrate cavity floor according to the invention can be generated by its non-combustibility is essential for space security  elevated.

Furthermore, the carrier plates according to the invention particularly solid and have a size of approx. 60 mm × 60 mm has a weight of approx. 5-10 kg. This will make a additional step and sound insulation of the cavity floor - reached.

The invention also opens up the possibility of building Change the room or the building from Alpha-Halbhy existing panels and body with little effort through environmentally friendly reprocessing processes to dispose.

Further developments and advantageous refinements of Invention are specified in further subclaims.

The invention is based on an embodiment with Explained in more detail with the help of several drawings.

Show it:

Fig. 1 is a sectional view through a fiction, modern floor cavity with differently formed supporting bodies,

Fig. 2 is a bottom view of the plane II of a frame with support body arrangement with Stützkör 1 pern the sectional profile according to FIG.

Fig. 3 is a hyperboloid support body in the central longitudinal profile section,

Fig. 4 a frusto-conical supporting body with sub legring in the central longitudinal profile section,

Fig. 5 is a plan view of a truncated cone-shaped support body in the direction of arrow V according to Fig. 4 and

Fig. 6 shows a detailed view of a support body and four carrier plate corners.

In the different figures of the drawing the same and functionally corresponding parts with the same reference digits.

In Fig. 1, a cavity floor 1 according to the invention is mounted above half of a prefabricated raw floor 2 .

The cavity floor 1 according to the invention has, as essential components, a multiplicity of supporting bodies 3 , a plurality of carrier plates 4 and a covering 5 .

The support body 3 are preferably grid-shaped on the raw floor 2 and carry the laid support plates 4 such that the support plates 4 form a support base 6 on which the covering 5 can be applied, so that the Aufla floor 6 and the covering 5 of the variety of Support body 3 are worn.

According to the invention, the essential components, in particular the support body 3 , the support plates 4 and the covering 5 , which is designed in particular as a screed layer, consist of a hardened binder system which essentially contains alpha hemihydrate and sand, the basis of which is obtained by flue gas desulphurization of REA gypsum is.

The support body 3 and the carrier plates 4 can be produced by introducing the liquid curable binder system into appropriately designed casting molds and by connecting the self-compacting hardening to elastic, loadable components. The carrier plates 4 are so stable and resilient that they can still be walked on completely after being laid on the support bodies 3 .

The covering 5 can be produced from a liquid screed, which likewise consists of the liquid binder system based on alpha hemihydrate. This liquid binder system can be processed by machine, is also self-compacting and can be cast with a flat surface.

The flowing screed has the property of self-distributing, smoothing and compacting. Shrinkage or swelling of the covering 5 during the curing process is particularly low.

Due to the elasticity of the carrier plates 4 and the self-generation of a flat surface of the covering 5 , the effort for leveling the support bodies 3 and carrier plates 4 can essentially be saved.

After the curing process of the originally liquid bandage by means of the system, the structure of the hardened bandage by means of the system is compressed in such a way that not only cuboid or cylindrical support bodies can be produced, but also tapering, in particular frustoconical, shapes can be executed. In general, the support body 3 , as shown in the sectional view in Fig. 1, with its larger footprint 8 in a grid on the bare floor 2 and carry with their smaller wing 7, the carrier plates 4th

Should the bare floor 2 have smaller and / or larger bumps, it is also possible to compensate for the distances that may arise between the wings 7 , the support body 3 and the carrier plates 4 . For this purpose, cutouts or openings are made in the carrier plates 4 , in particular in the area of the underlying supporting bodies 3 . Figs. 2 and 6 show that the carrier plates 4 advantageously in the corner rounded, truncated or otherwise recessed and thus in the "impact area" of four carrier plate corners (ie in the range in which four corners of four different support plates 4 meet ) together form an opening 10 .

The openings 10 preferably serve on the one hand the possibility of checking whether, in the case of a laid support base 6 with the support plates 4 , all the support bodies 3 are in the correct position according to the grid. On the other hand, it is possible to compensate through the openings 10, if necessary, distances between the wings 7 , the support body 3 and the carrier plates 4 by pouring in a viscous binding agent system or the like. So that the cast binder system is also properly held on the support surface 7 of the support body 3 , the support body 3 in the area of its support surface 7 preferably has a hemispherical or otherwise formed recess 11 ( FIG. 4), which is the positive and non-positive connection of the cast Binder system with the support body 3 is used. By pouring the support plates 4 in the region of the support body 3 , a compensation layer between the support surface 7 and the support plate 4 is formed after hardening of the binder system.

In order to compensate for larger bumps faster and easier, shims 9 are seen separately or in addition. On the one hand, these washers 9 can be placed separately on the supporting surface 7 of the supporting body 3 for distance compensation, whereby for a non-slip support they are preferably designed with holding projections which cooperate with the edge area and / or the recess 11 of the supporting surface 7 (not shown). On the other hand, the washers 9 can be underlaid and then cast with the viscous binder system. The washers 9 according to the invention can be produced by the same method as the support body 3 and the carrier plate 4th

A significant reduction in weight of the support body 3 can be achieved if, according to the invention, the support body 3 in the area of its standing surfaces 8 has a recess 12 directed into its interior, preferably a cone-shaped, frustoconical or the like.

Fig. 2 shows a bottom view of the unfinished floor 2 of a grid of support bodies in the direction of arrows II in FIG. 1. The support plates 4 supporting the support body 3 are in grid form, preferably the support plates surface extent corresponding to the subfloor 2 arranged . The support plates 4 are, as shown in Fig. 2, each with their corners in the center on the wings 7 of the support body by 3 , so that in this grid a support body 3 supports only support plate corners.

The carrier plates preferably have a size of 60 cm × 60 cm and a thickness of preferably 10-15 mm, the weight of which can be approximately 5-10 kg. The support plates 4 are resilient and fully walkable due to the design according to the invention, as a result of which a covering, in particular the liquid screed on the support plates 4 , can be applied easily and inexpensively.

The thickness of the processed, hardened screed layer is preferably about 30-40 mm. From these numerical Information is the resilience and the advantageous values the compressive and bending tensile strength is recognizable.

A further better carrying and stability of a support body 14 associated with a material saving can be achieved with its hyperboloid-shaped design.

With essentially the same size of the top and base surfaces 15 and 16 ( FIG. 3), an unproblematic position can be achieved, in particular with regard to the interchangeability of the top and base surfaces 15 and 16 of hyperboloid-shaped support bodies 14 on the unfinished floor 2 .

A slope layer 13 can be laid between the covering 5 and the support base 6 . The Schrenzlage 13 can be designed as a film or the like, for example made of plastic, in particular polyethylene. In another embodiment, it is conceivable to produce the Schrenz layer 13 from paper or the like, so that particularly environmentally friendly disposal is ensured.

The cavity floor 2 achieves an advantageous sound-insulating effect and is fully recyclable through the formation of its components with the hardened binder system based on alpha hemihydrate and sand.

It may be advantageous if, in addition, sound and / or thermal insulation is arranged through an insulation layer between the carrier plates 4 and the barrier layer 13 .

The invention is not limited to the illustrated and described exemplary embodiments, but also includes all forms having the same effect in the sense of the invention. For example, it would be conceivable not to design the recess in the carrier plate 4 in the corner region, but rather in the edge and / or surface region of the carrier plate 4 .

Claims (21)

1. cavity floor ( 1 ), which is arranged above a bare floor ( 2 ) and is provided with supporting bodies ( 3 ) which stand on the bare floor ( 2 ) and support plates ( 4 ) which form a continuous support floor ( 6 ) on which a covering ( 5 ) can be applied so that the support base ( 6 ) and the covering ( 5 ) are carried by the support bodies ( 3 ), characterized in that at least the carrier plates ( 4 ) consist of a hardenable binder system based on alpha -Half hydrate exist. 2. Raised floor according to claim 1, characterized in that the support body ( 3 ) consist of a binder system based on alpha hemihydrate. 3. Raised floor according to claim 1 or 2, characterized in that the covering ( 5 ) is a screed layer, which can be produced in particular as a flowing screed, which consists of the liquid hardenable binder system based on alpha hemihydrate. 4. cavity floor according to one of claims 1 to 3, characterized in that the binder system contains sand as an aggregate. 5. Raised floor according to one of claims 1 to 4, characterized in that the carrier plates ( 4 ) of the support base ( 6 ) in the binder system contain cellulose fibers and / or other inorganic and / or organic fibers, so that an elasticity of the carrier plates is achieved. 6. Raised floor according to one or more of claims 1 to 5, characterized in that the carrier plates ( 4 ) are rounded, chamfered or recessed in the corner region, so that an opening ( 10 ) is formed in the joint region of four carrier plate corners. 7. Raised access floor according to claim 6, characterized in that through the opening ( 10 ) the binder system in viscous form on the underlying wing ( 7 ) of a support body ( 3 ) is poured and after curing a leveling layer between the support surface ( 7 ) and the Carrier plate ( 4 ) is generated. 8. cavity floor according to one of the preceding claims, characterized in that the support body ( 3 ) are designed as a tapered structure, in particular frustoconical. 9. cavity floor according to one of the preceding claims, characterized in that a tapered support body ( 3 ) in the region of its standing surface ( 8 ) directed into its interior, preferably a cone-like, frustoconical or the like formed recess ( 12 ). 10. cavity floor according to one of the preceding claims, characterized in that a support body ( 3 ) in the region of its wing ( 7 ) directed into its interior, preferably a hemispherical or the like formed recess ( 11 ). 11. Raised access floor according to one of the preceding claims, characterized in that the supporting bodies ( 3 ) carrying the carrier plates ( 4 ) are arranged in a grid shape, preferably according to the carrier plates in terms of area on the bare floor ( 2 ). 12. Raised floor according to one of the preceding claims, characterized in that the support bodies ( 14 ) are hyperboloid-shaped, the top and base surfaces ( 15 ) and ( 16 ) are preferably the same size. 13. Raised floor according to one of the preceding claims, characterized in that a washer ( 9 ) to compensate for larger distances between the wing ( 7.15 ), the support body ( 3 , 14 ) and the carrier plate ( 4 ) is provided. 14. Raised floor according to one of the preceding claims, characterized in that the washer ( 9 ) consists of a binder system based on alpha hemihydrate. 15. Raised access floor according to one of the preceding claims, characterized in that between the covering ( 5 ) and the carrier plates ( 4 ) a Schrenzlage ( 13 ) is laid. 16. Raised floor according to claim 15, characterized in that the Schrenzlage ( 13 ) consists of paper. 17. Raised floor according to claim 15, characterized in that the Schrenzlage ( 13 ) consists of plastic, in particular of polyethylene. 18. Raised access floor according to one of claims 15 to 17, characterized in that between the Schrenzlage ( 13 ) and the support base ( 6 ) an insulation layer for the heat and / or tread sound insulation is arranged. 19. Raised floor according to one of the preceding claims, characterized in that the thickness of the carrier plates ( 4 ) is approximately 10 to 15 mm. 20. Raised floor according to one of the preceding claims, characterized in that the weight of the carrier plates ( 4 ) is approximately 5-10 kg with a carrier plate surface area of 60 cm × 60 cm. 21. Raised floor according to one of the preceding claims, characterized in that the thickness of the covering ( 5 ) is approximately 30 to 40 mm.