NL8102398A - PROCESS FOR THE EVEN DISTRIBUTION OF SPECIES OVER A SURFACE. - Google Patents

Description

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Method for evenly distributing mortar over a surface.

The invention relates to a method for uniformly distributing mortar, in particular screed mass, over a floor on which pipes are placed supported, and for obtaining a smooth surface of the mortar, respectively. of the screed mass, whereby the grout, resp. the screed mass is deposited in one place on the floor.

Evenly distributing mortar or screed mass over a floor requires high costs. The screed mass, which is supplied, for example, with the aid of a pump and which is poured in one place from a hose onto the floor, is then distributed over the floor with a shovel or the like and then with ironing devices, a mold or the like. leveled. The desired smooth and flat surface is thus obtained. Surface smoothing devices are used for the same purpose. These are devices with a vibrating bottom plate. These are passed over the already distributed screed mass. The vibrations make the surface smooth and smooth. At the same time, the screed mass is also compacted. This method, using one or the other tool, requires a lot of manual labor and time.

Preferably, the screed mass is relatively dry, resp. 8102398 * * - 2 - with a small amount of water. Evenly distributing and smoothing the surface requires a lot of work, as indicated above. The so-called liquid snare is used to avoid this. This is a screed with a large amount of water. The liquid bow is therefore relatively thin liquid. When it is poured into place on the floor, it automatically flows in all directions and spreads evenly over its surface. To promote this distribution or flow, sand with fine or very fine grains is added to the flow trap. However, the large amount of water in the flow bow and the fine or very fine grains that allow the flow to flow are only disadvantages. When drying, a strong shrinkage occurs, causing cracks. Plastics are added to the liquid trap to counteract this cracking. These plastics, however, increase the price of the liquid trap so that it can only be used in special cases. Even with a liquid bow, the problem is therefore not solved to obtain a smooth and flat surface without additional operations and / or machine costs.

Instead of cement, plaster or anhydrite has also already been added to the screed 25 as a binder. However, gypsum and anhydrite are not waterproof. As a result, the application possibilities of such a screed fall to practically zero.

It should be noted that so-called pear-shaped vibrators are known for compacting concrete 30 for load-bearing elements. These are cylindrical elements, which are inserted into the still damp concrete mortar and vibrated. As a result of the vibrations, the concrete also penetrates into narrow spaces within the formwork and is compacted at the same time.

8102398 »· * - 3 -

The object of the invention is to obtain an even distribution of the screed mass on floors on which pipes have been laid for underfloor heating. The solution for this stated purpose is achieved in a method of the above-mentioned type according to the invention, in that the mortar resp. the screed mass is vibrated by the introduction of pressure pulses into the tubes. Due to the pressure pulses introduced herein, the tubes vibrate over their entire length with a small, but with a sufficient amplitude to, respectively, the mortar. to vibrate the screed mass wherever it rests against the pipes. As a result, accumulations in places where the screed mass is dumped or supplied with a hose are discharged and evenly distributed over the entire floor. The screed mass assumes a completely smooth flat surface. Moreover, it is also compacted. The screed mass can be composed very dry with a small amount of water and also with coarse 20 grains. A great strength is thus ensured. Practice shows that a pile of screed mass, for example poured into a corner of a room, is visibly dissipated within a time of the order of magnitude of 25 seconds by the pressure pulses introduced into the tubes and is evenly distributed over the entire floor. When this mountain of screed mass is removed, it comes into contact with an increasingly larger pipe surface. This increases the intensity with which the screed mass is exposed to the vibrations. Thus, the screed mass is increasingly distributed and penetrates even the smallest cavities between and under the pipes and the supports that hold them. Finally, the screed mass is also compacted.

The tubes are preferably filled with a 81 0 2 3 9 ö * '· * * - 4 - ► liquid or gaseous medium and are connected with their ends to an impulse generator which is put into operation. The tubes preferably form a closed circuit of a heating or a cooling device with a forward and return flow.

The use of a rapidly switching pump is the preferred pulse generator. Likewise, a shock-acting pump can also be used. Water is preferred as the medium for filling the tubes. Any other liquid that does not react with the plastic of the pipes can also be used.

When using particularly dry screed masses or with a large floor area, it is preferred that the tubes for the introduction of the impulses are covered with a mat, in particular a mat consisting of building steel. The impulses are strongly transmitted to the screed mass by this mat. At the same time, the pipes in the screed-20 mass are prevented from coming up.

Exemplary embodiments of the present invention will now be explained in greater detail with reference to the description and accompanying drawings, in which: FIG. 1 is a perspective view of a room with pipes laid on its floor;

Fig. 2 is the same view as FIG. 1, the tubes additionally covered with a mat;

Fig. 3 shows the same picture as FIG. 2, where the screed mass has already been applied and the pulse generator has been activated;

Fig. 4 is a partial sectional view of the floor of the space shown in FIG. 3 at a location where the screed mass is poured; FIG. 5 shows the same picture as FIG. 4 at 8102398-5 * a later time at which the screed mass has already been distributed;

Fig. 6 gives the same picture as FIG. 4 at an even later time, when the screed mass is evenly distributed and its surface smoothed.

Fig. 1 schematically shows a part of a space with a floor 12. Rails 14 are placed thereon. These hold the pipes 16 of an underfloor heating system. These consist of a flexible plastic and are looped back and forth. The tubes 16 form a closed circuit with a lead 18 and a return 20. FIG. 2 corresponds to fig. 1. However, a mat 22, for example a mat of construction steel, also rests on the tubes 16. Optionally, this 15 is connected by means of wire to the rails 14 and / or the tubes 16.

Fig. 3 shows the same space at a later time when the screed mass has already been supplied via a supply hose 24. Under this hose the screed-20 mass 26 accumulates into a mountain. Furthermore, a pulse generator 28 is connected to the pre-run 18 and to the return 20 of the tubes 16. It is supplied with electric current via an electric supply line 30.

The pulse generator 28 can already be put into operation via the supply hose 24 during the supply of the screed mass 26. The lines shown in Fig. 3 along the forward and return run 18, respectively. 20 and arrows drawn vertically relative to the bars of the mat 22 indicate how the tubes 16 and the mat 22 are vibrated with a small amplitude 30. The mountain of screed mass 26 accumulated under the supply hose 24 is now discharged. The details are apparent from the following description of Figures 4-6. Fig. 4 shows a small mountain 32 of screed mass, as it has accumulated under the supply hose 24. At a later time, as indicated in Fig. 5, the pulse generator is already in operation. The drawn arrows indicate the vibrations to which the tubes 16, the rails 14 holding them, and the screed mass are exposed. This has already spread almost evenly over the total surface of the floor 12. However, the screed mass still shows a roughly corrugated surface 34. At a later time, as shown in fig. 6, this surface was also leveled and completely transitioned 10 in a smooth surface 36. At the same time, the screed mass has set and is also compacted.

Conclusions.

8102398

Claims (8)

1. Method for uniformly distributing mortar, in particular a screed mass, over a floor on which pipes are placed supported, and for obtaining a smooth surface of the mortar, respectively. of the screed mass, whereby the grout, resp. the screed mass is poured into the floor in a single place, characterized in that the grout, resp. the screed mass is vibrated by the introduction of pressure pulses into the tubes. Method according to claim 1, characterized in that the tubes are filled with a liquid or gaseous medium and are connected with their ends to a pulse generator, and that the pulse generator is put into operation. Method according to claim 2, characterized in that the tubes form a closed circuit of a heating or cooling device with a forward and reverse flow. 4. Method according to claim 2, characterized by the use of a rapidly switching pump as pulse generator. Method according to claim 2, characterized by the use of a shock-acting pump as pulse generator. Method according to claims 2-5, characterized by using water for filling the tubes. 7. Method as claimed in claims 1-6, characterized in that the tubes for the introduction of the impulses are covered with a mat, in particular a mat consisting of building steel. 8. Method substantially as described in the description. 8102398