ITMI20001536A1 - COMPOSITION FOR GLASS FIBER - Google Patents

Description

DESCRIPTION

The present invention refers to a new composition for glass fibers. As is known, mineral fibers and in particular glass fibers find wide application for the production of felts, marketed for example in the form of panels or rolls, typically intended in the civil sector to create thermal and / or acoustic insulation structures.

At the production level, the glass fiber felts are made in accordance with the process briefly described below.

Firstly, the material that forms the fiber at a high temperature until it reaches a physical state in which the glass takes on a fluid consistency. Subsequently, the fibers are formed and deposited on suitable conveyor belts forming felts of predetermined thickness. The phase of forming the fibers can for example be obtained by conveying the material in the fluid state inside suitable rotors equipped with numerous perimeter holes and capable of carrying out a centrifugal extrusion of the material which, subjected to the action of the combustion gases of a annular burner, it is reduced to very fine fibers. As mentioned above, the latter, suitably cooled and treated, are deposited on a conveyor belt forming a more or less homogeneous layer of fiber. Obviously the thickness of the felt that is formed can be determined by adjusting the speed of the conveyor belts as a function of the speed of formation of the fibers. Once the glass fiber felt has formed on the conveyor belt, one typically proceeds to compress the felt itself and pack it into panels or rolls.

One of the most delicate phases of the process described above is certainly the extrusion of the fiber carried out with the rotors perforated on the perimeter into which the fluid material flows continuously. It should in fact be noted that the holes with which the forming head must be provided are by their nature extremely small, having to make fibers with extremely

reduced. It is therefore clear that these holes easily lend themselves to being occluded. In particular, during the production of conventional glass fibers, the phenomenon of devitrification of the substantially liquid glassy material is very often observed; due to this phenomenology, in the liquid mass there is a tendency to the formation of crystals progressively increasing in size. It is evident that the formation of crystals inside the substantially liquid glass crossing the holes of the extrusion head can cause irreparable occlusions of the holes themselves. If the phenomenon of devitrification of the vitreous mass were to assume an uncontrolled trend, there would be a rapid operational deterioration of the extrusion head with the inability to produce and adequately form the fibers. It follows not only an enormous difficulty in controlling the quality of the felt that is gradually produced which, obviously, should have homogeneous characteristics in terms of thickness and fiber density, but also, in extreme cases, such damage to the extrusion head. to cause the shutdown of the entire plant and therefore maintenance and / or replacement of the extrusion head itself, with obvious economic and production damage.

In addition to the drawbacks described above, it should be noted that the presence in the vitreous mass of crystalline inclusions causes glasses with an inhomogeneous matrix which therefore leads to a decrease in the mechanical qualities of the glass, in particular in terms of resistance and elasticity, thus giving rise to scarcely competitive products. .

Having said these premises, it is a fundamental aim of the present invention to provide a new composition for glass fibers capable of substantially solving all the drawbacks mentioned above.

In particular, it is a fundamental part of the invention to make available a new composition of glass fibers capable of exhibiting excellent characteristics of fibrability without at the same time highlighting, at the fiber temperature of the fiber itself, significant devitrification phenomena. In greater detail, the composition for glass fibers object of the present invention must have an optimal processing temperature or fiber temperature (temperature at which the viscosity of the liquid glass mass is approximately equal to 1000 Poise), significantly different and higher than the temperatures in which the phenomena of formation and growth of devitrified crystals occur and propagate.

An additional object of the present invention is to devise a new composition for glass fibers which, in addition to being easily fiber-able and in addition to having a low or even insignificant tendency to devitrification, also has good characteristics in terms of biosolubility, i.e. the ability to be easily absorbed by a biological medium in predetermined time intervals.

In addition, the composition for glass fiber object of the present invention must give rise to felts with good mechanical characteristics, in particular in terms of elasticity, which allows a good mechanical behavior of the final product as well as an easier packaging of the same in small spaces. .

Finally, the composition for glass fibers in question must be capable of allowing the production of products such as panels or fibrous having excellent characteristics in terms of thermal and / or acoustic insulation.

These and still other objects, which will become clearer in the course of the following description, are substantially achieved by a composition for glass fiber according to one or more of the claims attached hereto.

Further characteristics and advantages of the present invention will become clearer from the description of some compositions for glass fiber according to the invention, provided in any case by way of indicative and therefore non-limiting example.

In order to better understand the detailed description of the glass fiber compositions designed by the applicants, it is useful to specify below some definitions that will occur in the course of the present discussion. First, the term devitrification will indicate the tendency for crystalline formations to arise within the matrix of the vitreous mass substantially in the liquid state. At the reference level, the stoichiometric compositions of the possible crystalline formations that can give rise to devitrification phenomena are the following:

β - wallastonite = CaO-Si02

Devitrite = Na20 3 CaO 6 Si02

Cristobalite = Si02

Diopside = CaO · MgO · 2 Si02

Tridymite Cristobalite = Si02

With liquidus temperature (T), expressed in degrees centigrade, it is indicated [a temperature at which we witness the beginning of the formation of the devitrifying crystals inside the liquid glass matrix.

The maximum speed of devitrification, expressed in microns / h (Vmax), means the maximum growth rate of the average size of the devitrifying crystals within the liquid glass matrix.

With maximum growth rate temperature (Tv (max)), expressed in degrees centigrade, we mean the temperature at which V max occurs, i.e. the maximum growth rate of the average size of the devitrifying crystals.

The temperature in which the viscosity η is substantially equal to 1000 Poise is meant by the optimal glass processing temperature (fiber temperature = Tf).

Having made these brief premises at the level of definitions, it should be noted that the studies of the applicants in order to obtain a satisfactory composition of glass fibers evidently started from the analysis of known compositions and from the study of the relative behaviors in order to understand, as far as possible , the effects that each component used in the composition could have with particular reference to the purposes that the applicants themselves had set themselves: workability of the glass, absence of devitrification problems, good mechanical qualities of the fiber, bio-solubleity.

For example, by analyzing the following composition C1 already available on the market for some time, in which the various components are given in percentages by weight,

it was noted that the performances obtained, although valid in terms of acoustic / thermal insulation of the fiber obtained, were not satisfactory with reference to other aspects.

In particular, for the above composition, in-depth experimental tests were carried out in the laboratory in order to determine Th Tv (ma *) and V max.

The tests were performed in accordance with the ASTM C-829 Standards Practices for measurements of liquids-Temperature of glass by gradient furnace method (annual book of ASTM standard Vol. 15, 1990 pages 266-274).

The devitrification curve of the known glass identified above in terms of percentage components, a curve obtained microscopically and referring to the β-wallastonite crystals, gave the following results.

T, = 876 ° C

T v (max) 829 ° C

V max = 2.19 micron / h

The devitrification parameters mentioned above and in particular the temperatures are decidedly high and lead to a glass in which, in the fibrous phase, wanting to operate at optimal viscosity, there is accentuated devitrification phenomena.

The studies of the applicants then turned in particular to the increase of alkaline oxides (Na20, K20) to the detriment of silica in order to obtain more fluid glass compositions, with a consequent decrease in both the liquidus temperature and the temperature of maximum devitrification speed. .

An attempt was also made to work on the percentages of alkaline earth oxides (CaO MgO) which have been decreased with respect to traditional values, again leading to a reduction in the liquidus temperature and the temperature of maximum devitrification speed.

Silica has also been significantly reduced compared to standard glass (such as the one analyzed in detail above), with a further advantage in terms of devitrification parameters.

In the formulations an attempt was made to combine the reductions in the components identified above with an appropriate rebalancing of the other components of the composition, taking into account the aforementioned need to obtain a fiber-capable, mechanically valid, bio-soluble and, obviously, economical material.

Surprisingly, it was noted that compositions in which the percentages by weight of each component fell within the ranges specified below were particularly valid from every point of view:

In particular, fibers have proved to be extremely valuable in which the ranges of percentages by weight of each component are within the following values:

By way of example, in compliance with the ranges indicated above, the following four specific glass fiber compositions were found to be extremely

advantageous:

In all the cases highlighted above, it was noted that the optimal fiber temperature remained in a range between 890-940 degrees centigrade and that the devitrification parameters obtained, both experimentally and mathematically, were decidedly good. In particular, T and Tv (max) were obtained respectively lower than 800 and 750 degrees centigrade with maximum growth rate V max <7 micron / h. The above data were verified and confirmed following experimental tests conducted in the laboratory according to the dictates of the recalled

ASTM standard, with reference to each of the compositions 1,2,3 and 4 in accordance with the invention. It should be noted that the lowering trend of T and Tv (mBX) is also shown by applying the mathematical model of Rodriguez Cuartas as shown in the table below:

The formula for calculating the devitrification parameters Pd is given by

fr multiplying factor referred to in the table above

p, = percentage by weight of the element Ύ

Psi02 = percentage by weight of the silica

Note that the above mathematical model is by its nature capable of providing only approximate values of the various devitrification parameters and it is certainly not possible to have a precise response, such as the experimental one, on the exact value of T, and Tv (max) ; the Rodriguez model gives in practice approximate indications on the tendency of the various parameters to increase or decrease as a result of the variation in concentration of the various oxides.

The improvement in terms of devitrification characteristics of the compositions devised by the applicants can be partially explained as follows. An increase in the alkaline oxides Na ^ KgO leads to more fluid glasses with a consequent decrease of T, and Tv (max).

A reduction of CaO and MgO also reduces,

CaO, T, and Tv (max).

In the same sense, the decrease of silica leads to a material decrease of T, and Tv (max) since Si02 is present in all devitrifying crystalline forms.

Even the lowering of Al203, in addition to having advantageous effects in terms of biosolubility, involves a reduction in the liquidus temperature and the maximum rate of formation of the devitrifying crystals; in any case, it should be noted that alumina has been reduced without however going below limits that would have jeopardized the structural stability of the glass matrix. With reference to the effects of the choices adopted on V (max), it should be noted that assuming the kinetics of crystal formation and in particular of β-wallastonite, of Devitrite, of Diopside as a function of the percentages of CaO and MgO, their decrease decreases by V (max).

V (max) is also reduced thanks to the replacement of part of Si02 with Na20 and, to a lesser extent, with K20, since the greater fluidity of the vitreous mass leads to a substantial kinetic equilibrium between the crystals (in particular of Devitrite) that are formed with the crystals that are constantly dissolving in the glassy liquid.

Thanks to the improved characteristics in terms of devitrification, the composition in question gives rise to better fibers also from a mechanical point of view.

In this regard, the high E ^ Og content makes it possible to obtain a highly elastic fiber with obvious advantages in terms of usability, handling and packaging of the product.

Finally, it is important to note how the compositions in accordance with the invention meet the most stringent biosolubility requirements; in particular, by defining the index Ki = ca0% + Mg0% + Ba0% + Na20% + K20% + B203% -2AI203%, the German standard TRGS905 provides, for the insulating fiber, Ki≥40, a relationship that is fully satisfied from the new compositions in accordance with the invention.

The invention achieves important advantages. In fact, it should be noted that all the newly conceived compositions, as well as proving to be excellent in terms of fibrability, excellent from a mechanical point of view and acceptable in terms of biosolubility, have increased considerably (on average by 30%) due to their low temperature of fibrability. the average life of the rotors used for the production of glass fibers.

Claims (26)

CLAIMS 1. Composition for glass fiber characterized in that it includes, in percentages by weight of the individual components: 2. Composition according to claim 1, characterized in that SiO2 is present in a percentage by weight of between 54.00% and 59.50% 3. Composition according to claim 2 characterized in that SiO 2 is present in a percentage by weight of between 56.40% and 58.90%. 4. Composition according to claim 2 characterized in that Ai203 is present in a percentage by weight comprised between 0 and 1%, preferably lower than 0.70%. 5. Composition according to claim 1, characterized in that Na20 is present in a percentage by weight of between 17.00% and 20.00% 6. Composition according to claim 1 or 5, characterized in that K20 is present in a percentage by weight of between 0.30% and 1.00%. 7. Composition according to claim 5 or claim 6, characterized in that Na20 is present in a percentage by weight of between 17.50% and 19.50%. 8. Composition according to any one of claims 5 to 7, characterized in that K20 is present in a percentage by weight of between 0.35% and 0.85%. 9. Composition according to claim 1, characterized in that CaO is present in a percentage by weight of between 3.00% and 7.00%. 10. Composition according to claim 9, characterized in that CaO is present in a percentage by weight of between 3.50% and 6.00%, preferably between 4.00% and 5.50%. 11. Composition according to claim 9 or claim 10, characterized in that MgO is present in a percentage by weight of between 0.% and 5.00%. 12. Composition according to any one of claims 9 to 11, characterized in that MgO is present in a percentage by weight of between 1.50% and 5.00%, preferably between 2.00% and 5.00%, the sum of the percentages by weight of CaO% MgO % being preferably less than 10.50%. 13. Composition according to claim 1, characterized in that BaO is present in a percentage by weight of between 1.00% and 2.00% 14. Composition according to claim 13, characterized in that BaO is present in a weight percentage varying between 1.40% and 1.80%. 15. Composition according to claim 1, characterized in that B203 is present in a percentage by weight of between 10.00% and 14.50%. 16. Composition according to claim 15, characterized in that B203 is present in a percentage by weight of between 11.00% and 14.00%. 17. Composition according to any one of the preceding claims, characterized in that it further comprises Fe203 in a weight percentage varying between 0.00% and 0.40%. 18. Composition according to claim 17, characterized in that Fe203 is present in a weight percentage varying between 0.05% and 0.20%. 19. Composition according to any one of the preceding claims having a fibrous temperature, corresponding to viscosity η = 1000 Poise, greater than 890 ° C, preferably between 890 ° C and 950 ° C. 20. Composition according to any one of the preceding claims characterized in that it has the following devitrification parameters: T, = Liquidus temperature ≤800 ° C; V max = maximum growth rate of devitrified crystals ≤7 micron / h; T v (max) ≤750 ° C; 21. Composition according to any one of the preceding claims characterized in that the percentages by weight of the following oxides present in the composition are such that: K, = CaO% MgO% BaO% Na20% K20% B203% - 2 Al203≥ 40 Composition according to any one of claims 1 to 21, characterized in that it comprises, in percentages by weight 23. Composition according to any one of claims 1 to 21, characterized in that it comprises, in percentages by weight 24. Composition according to any one of claims 1 to 21, characterized in that it comprises, in percentages by weight Composition according to any one of claims 1 to 21, characterized in that it comprises, in percentages by weight 26. Felt, for making thermally and / or acoustically insulating structures, obtained with the composition according to one or more of the preceding claims.