NL8005523A - Repairing worn and cracked industrial floor - by applying layer of resilient hydraulic mortar contg. latex with or without tiles - Google Patents

Abstract

Arrangement is intended for repairing a damaged (4,5) industrial floor (3) by applying a layer of mortar (7) on its surface. The mortar used is a resilient hydraulic mortar, e.g. made up of sand, cement and natural latex which may contain rubber particles. Tiles (9), such as concrete or acid-resistant natural stone tiles, may be placed on the mortar layer, and the joins (10) may be grouted with the same mortar material or with a chemically resistant grouting compound. The tiles may be covered by a plastic layer anchored by penetrating the non-grouted joins. A resilient layer, e.g. consisting of a meshwork covered by plastic foil or by foam plastic, may be applied as base for the mortar. Used for repair of industrial floor which has become damaged or developed cracks in use. Arrangement overcomes prior art problems. The proposed floor is applied and sets quickly, is tough, flexible and impact-resistant, is thinner, bridges cracks and resists thermal shock.

Description

X'i: 805102 / vdV / kd

Short indication: Method for repairing industrial floors.

The invention relates to a method for repairing commercial floors.

It is generally known that a large number of industrial floors can show damage after a shorter or longer period of time, which must be repaired.

The damage to the company floors, especially old company floors, can arise because either an existing tile layer has loosened or been torn, or that the underlay has loosened between the construction floor and the finishing floor on top, or the connection between a construction floor present on the construction floor. layer and a finished finishing floor is broken.

It has been proposed to repair such commercial floors by applying a new cement mortar layer over the old floor, but this layer appears in practice not to be sufficiently mechanically resistant, so that new damage is already visible after a short time. On the other hand, it has also been proposed to repair such damaged commercial floors by applying a synthetic floor. However, this solution has the drawback that the plastic floor to be applied must have a very large thickness of 15 to 20 mm in order to obtain a sufficient strength, while, moreover, such floors are very expensive.

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Another drawback of the plastic floors is their low resistance to temperatures above 70 ° C and low resistance to temperature lofts. Temperature! temperatures of more than 70 ° C and temperature shocks, however, often occur on company floors on which there are all kinds of machines and devices from which hot liquids can flow out, or devices that, for example, give off large amounts of heat during the day, while 8005523 -2- rv tr at night the floor has the opportunity to cool down, sometimes even to very low temperatures.

Yet another drawback of the use of a plastic floor is that the plastic can only be applied to a non-moist bottom layer, which is difficult to implement in practice.

Moreover, a relatively long time is required for the plastic to harden, so that the building in which the damaged industrial floor is located is then not usable for production purposes.

The object of the invention is now to provide a method for repairing company floors by applying a mortar layer on a company feather layer, which method is characterized in that at least one layer of elastic hydraulic mortar is applied and this layer is cured.

Such a method has the great advantage that the industrial floors can be repaired quickly, since an elastic hydraulic mortar hardens quickly and then forms a tough flexible layer of sufficient hardness that can be walked on quickly.

Another important advantage of this method is that it is possible to suffice with a small layer thickness of an elastic hydraulic mortar, so that less special provisions have to be made for existing frames, thresholds and the like. Moreover, such an elastic hydraulic mortar has the great advantage that small cracks in existing floors are bridged and the floor is resistant to mechanical and thermal shocks.

Since the elastic hydraulic mortar layer does not have to be attached to the underlying floor, this mortar layer is also more resistant to impact loads.

3q Finally, unevenness in the subfloor does not form any obstacles and can be quickly applied.

Particular advantage is to embed in the layer of elastic 8005523 f '* -3- \, (hydraulic mortar tiles, for example natural stones or concrete tiles.

Due to the fact that one can work with a relatively thin elastic hydraulic mortar layer, after embedding the tiles in the elastic mortar no floor is obtained with a very high height with all the associated disadvantages of (adjusting door thresholds and shortening of doors.

In case one wants to have a chemical resistant, in particular acid resistant, commercial floor, it is recommended to fill the joints between the tiles with a chemical resistant joint material.

advantageous * According to one / embodiment, a plastic covering layer can be applied. Especially when such a plastic layer is applied to a sub-layer consisting of concrete or natural stone tiles embedded in an elastic mortar, a very resistant plastic floor is obtained, which is presumably associated with the fact that, due to the good heat absorption capacity of the applied tiles, the plastic covering layer can tolerate a higher temperature without damage occurring. The heat supplied to the plastic covering layer is in fact easily absorbed by the concrete or natural stone tiles and distributed very evenly therein.

The invention will now be elucidated on the basis of an exemplary embodiment with the aid of the drawing, in which: fig. 1 shows a cross-section of a repaired industrial floor according to the invention; fig. 2 the same floor provided with a plastic covering layer; fig. 3 shows a similar floor as in fig. 1 with a film intermediate layer; In Fig. 1, a concrete construction floor 1 is shown with reinforcing bars 2 on which there is a commercial floor 3 which has damage 4 and cracks 5.

8005523 -4- J> «* '! K

An industrial floor 6 is located between the industrial floor 3 and the construction subfloor 1.

To repair the damaged company floor, a layer 7 of an elastic hydraulic mortar consisting of sand cement, natural latex and rubber particles, is applied to the damaged company floor. In this layer 7, a layer 8 of concrete tiles is laid.

After curing of the mortar, which takes place quickly, a layer is obtained which is sufficiently hard, but on the other hand has a flexibility due to the presence of the latex and rubber particles in the mortar.

The concrete tiles 9 are filled and filled in the elastic hydraulic mortar, while the joints 10 between neighboring tiles are filled with the same elastic hydraulic mortar.

15 For chemically resistant floors, it may be advisable to use chemical resistant tiles 9 and fill the joints 10 with a chemically resistant joint compound.

In particular, acid-resistant tiles are used, the joint 10 being filled with an acid-resistant material.

Fig. 2 shows another embodiment, in which concrete tiles 9 are laid in the layer of elastic hydraulic mortar, but without filling the joints 10.

A plastic covering layer 11 is applied to the whole, which also penetrates into the grooves 10 and therefore ensures a good anchoring.

Fig. 3 shows a similar floor as in FIG. 1, but before applying the mortar layer 7, a spring layer, such as a plastic film 12 supported by a braid layer 13, is applied to an existing damaged floor 3. Then 30 tiles 9 are applied. Instead of a plastic film, it is also possible to use a foam plastic layer 12 without braiding.

EXAMPLE I

80 U 5 5 2 3% -5- '; *

A layer of an elastic hydraulic mortar formed by mixing cement, water and a natural rubber latex is applied to a damaged industrial floor 3 which is located on an estrich floor 6.

The applied layer has a minimum thickness of 5 mm on the undamaged subfloor areas. Concrete tiles 9 with a thickness of 10 mm are laid in this layer. The joints between the concrete tiles are filled with the elastic hydraulic mortar mentioned above. After a relatively short time, the floor is walkable and highly resistant to vibrations and mechanical loads. EXAMPLE II

Example I is repeated, but a further 10 rubber threads are incorporated in the hydraulic elastic mortar. A particularly suitable industrial floor is obtained. The joints between the concrete tiles are filled with the elastic hydraulic mortar, as used in Example I.

EXAMPLE III

Example I is repeated, but after drying, an epoxy synthetic resin layer 11 with a thickness of 2 mm is applied to the top of the tile floor. The plastic layer is particularly resistant to temperature influences in places where the floor is subjected to heat, this heat is absorbed by the tile mass and is equalized.

, EXAMPLE IV

Example I is repeated, but natural acid-resistant tiles are used instead of concrete tiles. The joints between these nature-resistant tiles are filled with an acid-resistant joint compound.

EXAMPLE V

A layer 13 of 30 gauze is applied to a damaged industrial floor, on which a polyethylene foil 12 of 0.5 mm is placed. Hydraulic elastic mortar with 10 / S rubber threads, in which concrete tiles 9 are laid, is applied to the 8005523 9 w • η -6- foil layer 12. Such floors are extremely resistant to thermal and mechanical deformations since the floor layer of tiles can move prayer in the elastic mortar over the foil layer so that the subfloor layer or layers are not affected.

The plastic foil layer 12 acts here as a slip layer. A sufficient thickness of the foil layer partly determines the tear resistance of the floor, since shear stresses with the same fumigation can be higher with thinner plastic cells than with a thicker plastic foil with a thin film, virtually no shearing occurs.

8005523

Claims (8)

Method for repairing industrial floors by applying a mortar layer to an industrial floor layer, characterized in that at least one mortar layer of an elastic hydraulic mortar is applied and this layer is cured. Method according to claim 1, characterized in that the floor is provided with a plastic covering layer. Method according to Claim 1 or 2, characterized in that tiles, in particular concrete tiles, are embedded in the mortar layer of elastic hydraulic mortar. Method according to claims 1-3, characterized in that chemically resistant, in particular acid-resistant, tiles are applied. 5. Process according to claims 1-4, characterized in that the joints between the tiles are filled with a chemically resistant joint material. 6. Method according to claims 1-5, characterized in that a resilient layer is applied before applying the mortar layer of an elastic hydraulic mortar. Method according to claim 6, characterized in that the resilient layer consists of a plastic foil layer, whether or not supported by a braid. Method according to claim 6, characterized in that the resilient layer consists of a plastic foam. 8005523