ITVI20120033A1 - MIXTURE FOR THE PREPARATION OF A WATERPROOFING AND RELATIVE MEMBRANE MEMBRANE - Google Patents

Description

MIXTURE FOR THE PREPARATION OF A MEMBRANE

WATERPROOFING AND RELATIVE MEMBRANE

The present invention is part of the field of waterproofing membranes for building, and in particular it relates to a mixture for the preparation of a waterproofing membrane, based on modified bitumen, with a low specific weight compound. In detail, the membrane of the invention is obtained from a mixture of industrial bitumen modified with thermoplastic polymers and comprising a mineral filler consisting of a natural complex silicate of aluminum, sodium and potassium not chemically treated, with a density of 90 kg / mc / - 20 %.

The need to reduce the weight of the waterproofing bituminous membranes is strongly felt especially as regards their application on site, as their installation is still carried out manually.

The project focused precisely on the search for a light inert element that would not compromise the organoleptic performance of the bituminous compound or any other general performance of the membrane. For some time now, for the preparation of waterproofing membranes for building applications, mixtures including industrial bitumen, a mineral filler, a thermoplastic polymer or a mixture of thermoplastic polymers have been proposed, just as in the last two years membranes lightened with the use of cenosphere. However, the mineral filler typical of conventional blends remains calcium carbonate.

The adoption of calcium carbonate in a mixture of this type is able to significantly lower the price of the finished product, thanks to its low cost. However, this has the drawback of generating a large increase in density.

The compound comprising cenosphere, on the other hand, is characterized by a specific weight much lower than that of a compound comprising calcium carbonate, which allows the manufacture of membranes, with the same thickness, lighter than those manufactured with the compound comprising carbonate of calcium, while maintaining the mechanical resistance and performance characteristics of the membrane unaltered.

However, this solution is very expensive and significantly affects the final price of the membrane. Furthermore, the use of cenospheres involves a reduced cohesion of the bituminous matrix with the mineral filler.

The main object of the present invention is therefore to obviate the technical drawback described above and, in particular, to formulate a mixture for the preparation of a waterproofing membrane, which is lighter than the known art.

Another object of the invention is to formulate a mixture for the preparation of a waterproofing membrane, which offers better mechanical performances than those of the known art.

In particular, the object of the present invention is to formulate a mixture for the preparation of a waterproofing membrane, which is more resistant to the thermal shock actions induced by the installation operations.

These and other purposes, which will appear more clearly in the rest of the discussion, are achieved by a mixture for the preparation of a waterproofing membrane, by a relative membrane, and by the use of a natural complex silicate of aluminum, sodium and potassium as mineral filler. , respectively according to the attached claims 1, 7 and 9.

Further detailed technical characteristics are contained in the subsequent dependent claims. Advantageously, the mixture of the invention has a completely different behavior, during the mixing phases, with respect to known mixtures.

In particular, a greater cohesion of the bituminous matrix with the mineral filler is advantageously obtained.

Equally advantageously, the present invention provides a bituminous mixture characterized by a specific weight much lower than that of known mixtures, which allows the manufacture of membranes, with the same thickness, lighter than those manufactured with known mixtures, while maintaining the characteristics unaltered. performance of the final product. The bituminous membrane of the invention can be made in rolls which are significantly lighter than those currently on the market, and more resistant. The invention will now be described for illustrative but not limitative purposes, with particular reference to the following exemplary and preferred, but not limitative embodiment, as well as from the attached figures, in which:

Figure 1 is a photo under a scanning electron microscope (SEM) of a granule of a component of the compound of the invention;

figure 2 is a detail of figure 1;

Figure 3 is a scanning electron microscope (SEM) photo of a granule of a component of a known compound;

Figure 4 is a photo under a scanning electron microscope (SEM) of a granule of a component of a known compound;

figure 5 shows the dispersion under the fluorescence microscope of a component of the mixture of the invention according to a first example;

figure 6 shows the dispersion under the fluorescence microscope of a component of a known compound according to a first example;

figure 7 shows the dispersion under the fluorescence microscope of a component of the mixture of the invention according to a second example;

figure 8 shows the dispersion under the fluorescence microscope of a component of a known compound according to a second example;

figure 9 shows the dispersion under the fluorescence microscope of a component of the mixture of the invention according to a third example;

Figure 10 shows the dispersion under the fluorescence microscope of a component of a known compound according to a third example.

The invention relates to a compound for the preparation of a waterproofing membrane comprising industrial bitumen, a mineral filler and a mixture of thermoplastic polymers. In particular, the mineral filler consists of a complex silicate of aluminum, sodium and potassium that has not been chemically treated. The invention also relates to the use of this compound for the manufacture of bituminous waterproofing membranes characterized by a low specific weight. The invention is compatible with the manufacture of membranes belonging to different classes, which are defined by the cold flexibility values, measured according to the provisions of the EN 1109 standard, in the ranges from 0 ° C to -35 ° C.

The thermoplastic polymer used is at least one of those identified in the following categories: TPO, APAO, low density polyethylene, high density polyethylene, isotactic polypropylene, ethylene / propylene copolymer, ethylene / propylene / butene terpolymer, atactic polypropylene, styrenebutadiene-styrene block copolymer .

Preferably, they are used in percentages ranging from 8 to 25% of the total weight of the compound.

Industrial bitumen (preferably with penetrations from 100 to 300 dmm) is present in the membrane object of the invention in an amount comprised between 65% and 85% of the total weight of the compound.

The chemically untreated natural complex silicate of aluminum, sodium and potassium, available on the market under the name of Peralit 13, is present in an amount between 1% and 8% of the total weight of the compound.

The complex silicate of aluminum, sodium and potassium not chemically treated can be obtained from an effusive volcanic rock with a color varying between gray and pink, whose chemical composition is that of rhyolites and dacites. When subjected to temperatures between 850 and 1000 ° C, the rock expands due to the vaporization of the water; in this irreversible process, bubbles are generated inside the granules, which give the expanded rock the exceptional lightness that characterizes it.

The structure of the granules is characterized by the presence of open and closed porosities (figures 1 and 2). The simultaneous presence of these characteristics is such as to give the rock a high transpiring power and at the same time high impermeability to the water of the core of the granule.

Precisely due to its structure, Peralit 13 differs from traditional cenosphere (figure 3) for its ability to "pass" part of the bituminous matrix into the "voids" of the open pores, effectively incorporating it inside and making the whole compound more stable and less subject to possible breakdowns that could be caused by the thermal shock induced by the laying operations.

To make a waterproofing membrane sheet, it is necessary to use a reinforcing material. It can be, preferably, one of the following: a glass fleece, a glass fabric, a non-reinforced polyester non-woven fabric, a reinforced non-woven polyester fabric and finally a composite non-woven polyester fabric.

As mentioned above, bituminous membranes are classified according to the cold flexibility parameter, measured according to the EN 1109 standard which determines the minimum temperature to which the bituminous membrane must resist when folded into a mandrel with a predefined diameter.

The most common membranes on the market have flexibility from -5 <0> C to - 20 ° C.

Known compounds for each class are reported below:

MEMBRANE - 5 ° C (formulation expressed in% by weight)

Mechanical characteristics of the compound or compound: Cold flexibility (EN1109): -5 ° C

Penetration at 25 ° C (EN 1426): 17 dmm;

Penetration at 60 ° C (EN 1426): 85 dmm;

Softening temperature (EN1427): 110 ° C;

Viscosity at 180 ° C: 12,000 cps.

MEMBRANE - 10 ° C (formulation expressed in% by weight)

Mechanical characteristics of the compound:

Cold flexibility (EN1109): -10 ° C;

Penetration at 25 ° C (EN 1426): 22 dmm;

Penetration at 60 ° C (EN 1426): 100 dmm;

Softening temperature (EN1427): 120 ° C;

Viscosity at 180 ° C: 9,200 cps.

MEMBRANE - 15 ° C SBS (formulation expressed in% by weight)

Mechanical characteristics of the compound:

Cold flexibility (EN1109): -15 ° C;

Penetration at 25 ° C (EN 1426): 25 dmm;

Penetration at 60 ° C (EN 1426): 110 dmm;

Softening temperature (EN1427): 110 ° C;

Viscosity at 180 ° C: 9,600 cps.

Compared to known compounds, the compound of the invention has a total absence of calcium carbonate. Moreover, advantageously, with the mixture of the invention a greater interaction between the charge and the bituminous matrix is obtained during the mixing step; this guarantees greater resistance to thermal "stress" that could be induced by the laying operations.

The invention is described in greater detail by means of the examples given below, to be considered demonstrative, but certainly not exhaustive, of the novelty object of the technological discovery.

EXAMPLE 1: membrane flexibility -5 ° C

(formulation expressed in% by weight)

Mechanical characteristics of the compound:

Cold flexibility (EN1109): -5 ° C;

Penetration at 25 ° C (EN 1426): 20 dmm;

Penetration at 60 ° C (EN 1426): 80 dmm;

Softening temperature (EN1427): 110 ° C;

Viscosity at 180 ° C: 11,200 cps.

From the above it is clear that the technical characteristics of the membrane are maintained. The weight of the roll is 14 kg less than in the known art. From the analysis of the dispersion with a fluorescence microscope (Figures 5 and 6) it is possible to infer a greater compatibility of the Peralit charge with respect to the cenosphere.

EXAMPLE 2: membrane flexibility -10 ° C

(formulation expressed in% by weight)

Mechanical characteristics of the compound: Cold flexibility (EN1109): -10 ° C;

Penetration at 25 ° C (EN 1426): 27 dmm;

Penetration at 60 ° C (EN 1426): 107 dmm;

Softening temperature (EN1427): 120 ° C;

Viscosity at 180 ° C: 10.100 cps.

From the above table it is clear that the technical characteristics of the membrane are maintained. The reduction in the weight of the roll is 10 kg with respect to the known art. From the analysis of the dispersion with a fluorescence microscope (Figures 7 and 8) it is possible to see a greater compatibility of the Peralit 13 charge with respect to the cenospheres.

EXAMPLE 3: membrane flexibility -15 ° C (SBS)

(formulation expressed in% by weight)

Mechanical characteristics of the compound:

Cold flexibility (EN1109): -15 ° C;

Penetration at 25 ° C (EN 1426): 32 dmm;

Penetration at 60 ° C (EN 1426): 100 dmm;

Softening temperature (EN1427): 110 ° C;

Viscosity at 180 ° C: 8,620 cps.

From the above table it is clear that the technical characteristics of the membrane are maintained. The reduction in the weight of the roll is 6 kg with respect to the known art. From the analysis of the dispersion with a fluorescence microscope (Figures 9 and 10) it is possible to infer a greater compatibility of the Peralit 13 charge with respect to the cenospheres.

From the above description the characteristics of the mixture for the preparation of a membrane and of the relative membrane, which are the object of the present invention, are clear, as are the advantages.

The preferred embodiments have been described previously and variants of the present invention have been suggested, but it is to be understood that those skilled in the art will be able to make modifications and changes without thereby departing from the relative scope of protection, as defined by the attached claims.

Claims (9)

CLAIMS 1) A mixture for the preparation of a waterproofing membrane, comprising industrial bitumen and a mineral filler, characterized in that said mineral filler includes natural complex silicate of aluminum, sodium and potassium. 2) A mixture according to claim 1, characterized in that said industrial bitumen has penetrations ranging from 100 to 300 dmm. 3) A mixture according to one of claims 1 or 2, characterized in that said industrial bitumen is present in an amount comprised between 65% and 85% of the total weight of the mixture. 4) A mixture according to one of claims 1-3, characterized in that said natural complex silicate of aluminum, sodium and potassium is present in an amount comprised between 1% and 8% of the total weight of the mixture. 5) A mixture according to claim 4, characterized in that said natural complex silicate of aluminum, sodium and potassium is present in an amount corresponding to 3% of the total weight of the mixture. 6) A mixture according to claim 4 or 5, characterized in that said industrial bitumen is present in a percentage of the total weight of the mixture, corresponding to one of the following values: 82%, 77%, 85%. 7) A waterproofing membrane prepared with a mixture according to one of claims 1-6. 8) A waterproofing membrane according to claim 7, characterized in that it comprises at least one reinforcement material among the following: a glass veil, a glass fabric, a non-reinforced polyester non-woven fabric, a reinforced non-woven polyester fabric, a polyester composite non-woven fabric. 9) Use of a natural complex silicate of aluminum, sodium and potassium as a mineral filler in a mixture for the preparation of a waterproofing membrane.