SK1097A3 - Compositions of glass for mineral wool production - Google Patents

Abstract

The invention relates to glass compositions for the manufacture of mineral wool having favourable physiologic properties as well as good production technical, production economical and product favourable properties. The glass composition contains SiO2 in the amount of 45-55 % by weight, Al2O3 in the amount of 0-8 % by weight, B2O3 in the amount of 0.3-5 % by weight, Fe-oxides in the amount of 0-10 % by weight, alkalic earth oxides in the amount of 32-45 % by weight and alkalic oxides in the amount of 0-6 % by weight. Also favourable relationships of different oxides are defined.

Description

Technical field

The invention relates to a mineral wool glass composition which is more suitable from a health standpoint than asbestos, which is at risk of lung cancer.

BACKGROUND OF THE INVENTION

Based on the epidemiological investigations carried out, there has been no evidence of a relationship between working with mineral wool and lung cancer or any other disease. Also, inhalation tests in which animals inhaled a large amount of mineral wool fibers did not lead to the detection of increased cancer. These results relate to commercially obtainable fibers and it is not clear to what extent the results can also be applied to other types of fibers. Therefore further research is needed.

However, it is very costly to carry out epidemiological and inhalation studies that last very long, even several years. Epidemiology is also relatively insensitive. Therefore, attempts have been made to develop a method for analysis, i. to obtain a method for identifying the types, in this case, the types of mineral wool fibers that may be at risk of developing the disease. Cases identified in this way may later be subjected to more thorough tests to determine whether or not there is an acute risk. Another aspect is that the types of fibers that give results for properly performed analytical tests can be considered risk-free for disease induction.

The analytical assays may be IP assays, intraperitoneal or intrapleural delivery, i. introduction of fibers into the abdominal cavity and into the pleura of the test animals.

Such tests can be considered very sensitive and with few false negative results, i. cases in which material capable of causing disease risks can in fact be considered harmless in tests. Conversely, a large number of false positive results can be obtained. So far there is very little knowledge.

IP tests can also be costly and take several months. It is also unethical to use experimental animals for these purposes. Therefore, in vitro methods have been tested that can be performed with available equipment and within a few days. These methods are in two categories: biochemical and chemical.

In biochemical methods, fibers are contacted with living cells or cellular materials and biochemical reactions, such as free radical formation, are investigated.

Chemical methods are often based on phenomena in which mineral wool fibers can be dissolved in polar liquids, such as liquids that mimic body fluids. It is believed that fibers that dissolve rapidly or disintegrate into very short pieces pose little or no risk.

It was assumed that the chemical classification was to be performed prior to the IP test, thus reducing the number of fiber types to be tested for IP. Thus, an index indicating the fiber glass composition was created and the composition was divided into three groups: the first group that is likely to pass the IP test, i. a group giving a negative result; a second group for which it is reasonable to assume that the glass composition cannot fully pass the IP test; and the third category, which is a group for which the overall probability cannot be ascertained by means of an index, and therefore must be subjected to IP tests.

The index according to this idea is the Wardenbach index (WI), which is calculated from the equation

VVI = BaO + CaO + MgO + Na2O + K2O + B2O3 ⁺ 2AI2O3

The creators of this index assume that fibers with a diameter <3gm and a length greater than three times the diameter are unlikely to become loose in the standardized IP test if WI is less than 25, and vice versa if WI is greater than or equal to 40. At 25 <WI <40 different evaluation is required.

The Wardenbach index appears to be of an empirical construction that relates to glass with some instability that can cause a truly high solubility, i. short fiber life in the body.

However, solubility is not the only determining property of the fiber. Other features are morphology and the ability to break into fractions. This index also does not indicate the technical usefulness of the glass, for example the melting ability, the spinning or other properties of the fibers produced from the glass in question.

The fiber solubility is a particularly complicated phenomenon. Several studies in this field have been conducted, for example by Scholz and Condradt, "An in vitro study of the chemical durability of siliceous fibers", Ann occup. Hyg., Vol. 31, no. 48, pp. 683-692, 1987. What caused the situation complicated is that the fibers can be attacked by the conducting liquid in at least four different ways. The first option is a homogeneous solution, i. when the glass fiber ions reach the solution at the same rate over the entire surface of the fibers without visible change on the remaining glass. The second option is selective dissolution, in which certain ions are more easily dissolved than other ions. That is, the remaining glass is depleted of said dissolved ions. Both options reduce the diameter of the fibers over time, but substantially evenly over the length of the fiber.

The third way is to convert the glass of fibers into a gel to a certain depth. The gel layer is then broken and a new gel layer is formed. This method also results in a substantially uniform diameter reduction over the entire fiber length.

A fourth possibility is to form cavities or grooves on the fiber surface layer. The cavities may be relatively deep and may be partly a reason for breaking the fibers into short pieces in the tissue. This phenomenon is often observed in animal tests. Shortening the fibers facilitates the movement of the fibers. It is assumed that fibers below a certain minimum length, which is referred to in various strands as 5 - 20 gm, are not carcinogenic.

In short, this means that a fiber whose size can cause cancer can be reduced in one or more ways. The study of this variable mechanism is important in the context of medical circumstances. Unfortunately, there is no complete theory why different types of fibers act differently, as mentioned above, and the existing hypotheses partially contradict each other. One of the reasons is experimental difficulties. It is a question of microscopic scale procedure in which conditions are heterogeneous. The pH value is of great importance in this context. The pH is not the same inside and between cells. It has been found that this difference may be one of several important parameters in terms of fiber breakdown.

In explaining the differences between the different fibers, differences can be found in the chemical composition, the inhomogeneity of the chemical compositions and the micro-tensions in the fibers caused by the very rapid cooling to which the glass undergoes spinning. Also, debris in the fibers, air bubbles and encapsulated particles can be an explanation.

To a large extent, experiments are carried out in vitro and this need makes the technical model and nature of observation very compromise. Therefore, fibers with larger sizes than the breathable fibers are preferably used. It is not necessary to use physiological liquids, but to simulate such solutions as Gamble's solution, which contain optional organic components.

Observation can be quantified only partially and its interpretation is mostly subjective. Therefore, its reproducibility is not easy.

The present invention is based, in part, on model-scale fiber studies in which a multi-pound mineral batch is melted in an electric furnace, after which the molten mineral is spun in a so-called &quot; a cascade machine in which molten mineral is fed to the outer surface of a rapidly rotating internally cooled spinning steel cylinder. From there, the molten mineral is partially drawn in the form of fibers and partially drawn to the next spinning wheel, etc.

A study was carried out on deposited proportions of thin fibers. Another study was carried out on individual continuously produced fibers. The fibers were exposed to a variety of chemical environments and were studied by conventional chemical analysis, electron microscope (SEM), for chemical analysis of small sections and for observation of surface changes.

Technical glass, which is found in mineral wool fibers, contains several major oxides which interact in a complex way. Of course, the main purpose of some of these oxides is known for some compositions, but the details are not entirely known with respect to the overall interaction. In a system of only three components, for example Si, Al and Na oxides, in which the area in the three-dimensional coordinate system can be found in terms of volume, stable glass can be produced. Then, different volumes can be detected, i. areas that have different properties. Stepped transitions do not exist, but the regions must be defined by a single property, such as solubility, measured by a particular method.

Within each area there must be at least one point which, when examining the property, represents a threshold value, or a maximum, respectively. minimum value. Since such extreme curves often have different characteristics, it may be difficult to define the exact boundary point.

Since technical glasses contain much more components than the above three components, in practice the question of n-dimensional volumes and areas in the n-dimensional system arises.

Several areas have been identified in which properties appear to be advantageous, as seen from the possibility that fibers of such a composition should give negative results in IP tests.

Such observations are not sufficient to detect technically applicable compositions for mineral wool fibers. It is also necessary that the glass has good meltability, allows spinning with good yields, and that the material is economical to produce and provides fibers and wool of suitable properties. Therefore, production scale tests and finished product tests were also carried out.

Such an assessment also has several subjective elements. After a large number of tests, it was possible to further define the areas considered to be advantageous for chemical evaluation. The invention therefore relates to compositions which have a favorable environmental performance and are also suitable for the rational production of mineral wool having good properties for the product used.

In practice, it is often not possible to change a single glass oxide relative to other oxides. Normally, however, variations from several oxides are obtained in parallel. These difficulties can be overcome by processing test data using statistical methods, such as multi-factor analyzes, where the significance of individual oxides can be determined. In such analyzes, various variables and secondary variables, which are functions of some primary variables, can also be envisaged.

A complete analysis of biologically interesting properties in vitro revealed important production factors and other fiber properties using statistical methods. Composition areas of great importance have been identified. The following table contains the amount in% by weight in three stages, A, B and C. The table is to be understood that for a certain oxide, disregarding the values of other oxides, the region A is at least desirable, B is the better choice and C is the best . If there are a number of oxide changes outside Area B that are within Area B, a visible improvement is obtained even when other oxides are present outside Area B.

SUMMARY OF THE INVENTION

The present invention provides mineral wool glass compositions in which the glass in molten form is fed to a fiberising apparatus.

The principle of the invention is that the glass comprises in region A the following oxides, expressed in% by weight:

oxide A B C SiO ₂ 45-55 46 - 50 47 - 49 A1 ₂ O ₃ <8 <6 <4 b ₂ o ₃ 0,3 - 5 0,5 - 5 1 - 4 FeO + Fe ₂ O ₃ <10 <8 <6 CaO + MgO 32 - 45 35-42 36-40 Na ₂ O + K ₂ O <6 <4 <2

The compositions of the invention have composition A and additionally contain 0.3 to 5% by weight of boron oxide.

The meaning of the table is that, for example, if the Al ₂ O ₃ content is less than 5 to 3% by weight, a noticeable improvement in the overall assessment of glass usability is obtained. The content of B ₂ O ₃ may advantageously be lower because the effect is already obtained with small amounts thereof. It is considered to be in need of at least 0.3% by weight.

Total iron oxide is expressed as FeO, total alkaline earth as CaO, and total alkali oxides such as Na ₂ O. In the compositions of the type described, there may be smaller amounts of other oxides, such as Mn and Ti oxides. Experience has shown that amounts of 0.5-2% by weight are suitable.

The addition of phosphorus has a beneficial effect when added in amounts of 1 to 4% by weight.

In addition to the above, compositions may be found in which BaO + CaO + MgO + Na ₂ O + K ₂ O + B ₂ O ₃ -2Al ₂ O _3, all by weight, is greater than 30, even greater than 40. The invention explicitly includes such compositions.

The studies leading to the invention as described above show that the ratio B ₂ O ₃ / Al ₂ O ₃ , calculated in% by weight, is important. The ratio should preferably be greater than 0.2, in particular greater than 0.4.

The MgO / CaO ratio is also important.

The invention is further defined by the claims.

The composition according to the invention is in terms of the SiO ₂ content in the area in which rockwool wool is commonly found. The boron-containing one is described in Danish patent application no. However, the addition of boron to the rockwool wool glass does not lead to usable glass. At the same time, the amount of Al ₂ O ₃ should be reduced.

The glass compositions according to the invention are especially adapted for melting in coupon furnaces or electrode furnaces with subsequent spinning by means of a cascade spinner.

Claims (17)

1. Mineral wool glass compositions in which the glass in molten form is fed to a fiberising apparatus in which fibers are formed, characterized in that they contain, by weight, these oxides SiO ₂ 45-55 ai ₂ o ₃ <8 ^B 2 ° ₂ 0,3 - 5 FeO + F ₂ O ₃ <10 CaO + MgO 32 - 45 Na ₂ O + K ₂ O <6 wherein the total iron oxide content is expressed as FeO, the total alkaline earth content as CaO and the total alkali oxide content as Na ₂ O. Glass copolymers according to claim 1, characterized in that they contain at least 46% by weight, preferably at least 47% by weight of SiO ₂ . Glass compositions according to claims 1 and 2, characterized in that they contain at most 50% by weight, preferably at most 49% by weight of SiO ₂ . Glass compositions according to one of the preceding claims, characterized in that they contain at most 6% by weight, preferably at most 4% by weight Al ₂ O ₃ . Glass compositions according to any one of the preceding claims, characterized in that they comprise at least 0.5% by weight, preferably at least 1% by weight of B ₂ O ₃ . Glass compositions according to one of the preceding claims, characterized in that they contain at most 5% by weight, preferably at most 4% by weight of B ₂ O ₃ . Glass compositions according to any one of the preceding years, characterized in that they contain at most 8% by weight, preferably at most 6% by weight, of iron oxides, calculated as FeO. Glass compositions according to any one of the preceding claims, characterized in that they comprise at least 35% by weight, preferably at least 36% by weight, of alkaline earth oxides, calculated as CaO. Glass compositions according to any one of the preceding claims, characterized in that they contain at most 42% by weight, preferably at most 40% by weight, of alkaline earth oxides, calculated as CaO. Glass compositions according to one of the preceding claims, characterized in that they contain at most 4% by weight, preferably at most 2% by weight, of alkali oxides, calculated as Na ₂ O. Glass compositions according to any one of the preceding claims, characterized in that they further comprise 0.5 to 2% by weight of manganese oxide. Glass compositions according to any one of the preceding claims, characterized in that they further comprise 0.5 to 2% by weight of titanium oxide. Glass compositions according to any one of the preceding claims, characterized in that they further comprise 0.5 to 5% by weight of P ₂ O ₅ . Glass compositions according to one of the preceding claims, characterized in that they further comprise at least 1% by weight, preferably at least 3% by weight, of iron oxides, calculated as FeO. Glass compositions according to any one of the preceding claims, characterized in that they comprise at least 30% by weight, preferably at least 40% by weight. CaO + MgO + Na ₂ O + K ₂ O + B ₂ O ₃ H ₂ -2A1 _third Glass compositions according to any one of the preceding claims, characterized in that they contain boron oxide and alumina in a ratio of B ₂ O ₃ / Al ₂ O _{3 of} greater than 0.2, preferably greater than 0.4, expressed in% by weight . Glass compositions according to any one of the preceding claims, characterized in that they contain manganese oxide and calcium oxide in a MgO / CaO ratio of greater than 0.15, preferably greater than 0.2, expressed in% by weight.