DE2451121A1 - Glass ceramic prepn. from lithium oxide-contg. glass - by heating to crystal nucleating and crystallisation temp. for defined periods - Google Patents

Abstract

Glass ceramic is prepd. by (a) forming a glass body consiting by wt. of 6-20 (pref. 12.6) % Li2O, 0-10, (4.8) % Al2O3, 70-80 (78) % SiO2, 0.5-6 (2.5) % P2O5, 0-10 (3.2) % B2O3, 0-6, (5.1) % K2O and 0-5 (O); Zno; (b) heating to crystal nucleating temp. 550-600 (pref. 575) degrees C and keeping at this temp. for 0.5-1 (pref. 0.5) hrs. (c) further heating to crystallisation temp. 850-870 (860) degrees C and keeping at this temp. for 0.5-1 (0.5) hrs. and (d) cooling to room temp. The glass ceramic is used for electrical insulators, cooking utensils and protective casings for radar aerials. By this process a glass ceramic of improved strength is obtd. with shorter heat-treatment times.

Description

Process for the production of glass ceramics Glass ceramics are materials which were first melted and processed into glasses, but which then went through controlled crystallization were partially converted to a crystalline state. In general, the process comprises melting a glass-forming mixture, in which a means for crystal nucleation or

a crystallization-promoting agent has been introduced, wherein at the same time the melt is shaped and cooled to a glass body and then the body after heated according to a specific heating scheme. To this Way, the glass is transformed into a body made of finely grained, arbitrary oriented crystals dispersed substantially uniformly in a glass matrix are composed. One such method is described in U.S. Patent No. 2,920,971. The physical properties of glass ceramics are closer to those of conventional ones Ceramics than those of the original glasses and these properties maclien the glass ceramics useful as electrical insulators, cookware and protective housings for radar antennas.

A glass ceramic material with high mechanical strength and good electrical properties are described in US Pat. No. 3,066,775. This material is based on the Li2O-Al2O3-SiO2 system and it also contains small amounts of one crystal nucleating agent such as P2O5, ZrO2 or TiO2. So far, glass compositions have been in the areas of controlled crystallization described in US Pat. No. 3,066,775 by heat treatment at a temperature of about 650 to 700 ° C for 0.25 to 2.5 Hours, followed by heating to 900 to 1,000 ° C for one to eight hours exposed to produce a glass-ceramic, the lithium disilicate as the only one contains crystalline main phase. The one required for the heat treatment program Total time was about 16 hours.

In the present invention is an improved method of manufacture a glass ceramic has been found, which comprises the heat treatment of a glass body, which essentially consists of the following components in% by weight; 6-20 Li2O, 0-10 Al2O3, 70-80 SiO2, 0.5-6 P2O5, 0-10 B2O3, 0-6 K2O and 0-5 ZnO by making the glass body to a nucleation temperature of heated and a half holds at this temperature for one hour and then further to a crystallization temperature from 850 to t700c and heated at this temperature for about half an hour to an hour and then allowed to cool to room temperature. The one after the improved Glass ceramic prepared by the method according to the invention contains a crystalline main phase made of lithium disilicate and reinforced strength properties can be achieved via the after the known method achievable addition can be obtained.

The raw materials for the blend composition are weighed out and mixed, e.g., by ball milling or the like, and then at a temperature melted from about 1200 to 1300 OC to form a homogeneous melt. the Melt is then made into any desired shape using conventional methods Glass molding techniques preformed. One such method of making a cylindrical (bushing) configuration is described in the aforementioned U.S. Patent 3,006,775. to at this stage, the molded product is an amorphous vitreous material without any Crystals in it.

The heat treatment scheme involves heating the rather slowly Glass up to a nucleation temperature, keeping the temperature for a certain time to introduce a large number of crystal nuclei into the material, around which the subsequent crystalline growth can take place and then the slow one Raise the temperature up to the crystallization temperature, hold at that temperature for another period and the relatively slow cooling to room temperature. Though the precise heat treatment for nucleation and crystal growth will vary slightly depending on the original glass composition, it was found that generally the optimal conditions for are the nucleation of heating to a temperature of 550 to 600 ° C and holding at such a temperature for 1/2 to 1 hour and so on Heat up to a crystallization temperature of 850 to 8700C and hold at this temperature from 1/2 to 1 hour.

The invention is described below with reference to the drawing explained in more detail.

In detail: Fig. 1 time / temperature curves for a preferred Heat treatment scheme according to the present invention, compared with one so far usual scheme, Fig. 2 is a graph of the strength properties the preferred composition as a puncture of the growth temperature and FIG. 3 a graphical representation of the crystal phase distribution as a function of the growth temperature.

In Figure 1, two specific heat treatment schemes are shown for the casting of glass items made from a preferred composition, such as it is defined in the following example 1, are prepared. The preferred heat treatment according to the present invention, referred to as Scheme A, consists of heating holding the glass article to a nucleation temperature of 575 ° C at this temperature for half an hour and subsequent heating to one Crystallization temperature of 860 ° C and holding at this temperature for one half a hour. The article is then slowly cooled to room temperature. the Total time for Scheme A is about .0 hours. A heat treatment, as it has been commonly used is designated as Scheme 13 and it exists from heating the glass item up to a temperature of 640 ° C at that temperature for one hour, followed by heating to a temperature of 8300C and holding for four hours and dajnacit allowing to cool to room temperature. The total time for Scheme 3 is approximately 1G hours.

A comparison of these two meat schemes shows that this improved The method of the present invention saves a considerable amount of time brings a greater effectiveness in furnace operation and so an essential.

economic advantage.

The gas composition used in Figures 2 and 3 was preferred of Example 1,. Which had been related to Giasstäben, which is a seed crystal had exposed the formation stone temperature of 645 0 for one hour. After that, the crystal nucleus-containing glass rods, as shown in Figure 3, a heat treatment for Crystal growth exposed for four hours at different temperatures. the Results are graphed to show that at a temperature below from 750 ° C the predominant crystal phase is lithium metasilicate. When the temperature is increased to 750 to 950 C, then the predominant crystal phase becomes lithium disilicate. These crystal phases were determined by X-ray diffraction clinics. Thereafter. the heat-treated bars were rolled around for 25 minutes (corresponding to about 60 microns) ground in silicon carbide with a grain size of 240 gritl.

The tensile strengths of the ground rods were according to the standard Determined four-point bending. The data obtained are shown graphically in Figure 2, in which the strengths are given in nilopounds per square inch and the crystal phases correspond to those of Figure 3. For comparison, let the tensile strengths of the starting glass which has been subjected to such a surface preparation and they are around 790 to 1,050 kgXcm2 (corresponding to 10 to 15 Kilopounds per square inch). From the data shown graphically in Figure 2 it was determined that the presence of lithium metasilicate crystals in the glass.

ceramic has no noticeable effect on tensile strength. If the However, lithium disilicate becomes crystalline phase, then the tensile strength increased of the glass-ceramic was considerable and then it was in the range from about 1,500 to 4,900 kg / cm (equivalent to 22 to 70 kilopounds per square inch).

To create the desired microstructure, i.e. a maximum Volume fraction of lithium disilicate phase in the shortest possible time, it was found that the original nucleation is the subsequent growth of the special crystalline phase controls. It was also stated that in the above Glass composition, although some overlap in the nucleation of lithium metasilicate and lithium disilicate takes place, the preferred nucleation of lithium disilicate takes place at a temperature below 600 ° C and the preferred nucleation of lithium metasilicate takes place at temperatures above about 6000C. After preferred nucleation of lithium disilicate is the optimal temperature for a maximum crystal growth rate of the disilicate at about 850 to 870 0c, which, as can be seen from FIG. 1, takes place very quickly.

But even after a preferred nucleation of lithium metasilicate the metasilicate is at elevated temperatures above 800 ° C, as in Figure 3, converted to the disilicate. but with a much more gradual one Speed leading to a total increased total heating time leads.

X-ray and microstructure studies show that the increased Strength caused by wax temperatures above 85,000 Surprisingly, both with an increase in grain size and with a decrease the maximum volume fraction of the lithium disilicate phase is connected. One such Result was unpredictable and it is contrary to what in general was assumed, namely that the strength of a ceramic article decreases, when the grain size decreases.

The invention is explained in more detail below with the aid of examples. Unless otherwise specified, the compositions are in weight and mol% stated as calculated from the oxide-based mixture. The original glasses were prepared by melting the blend ingredients under standard conditions at temperatures of 1200 to 1600 ° C for about 4 to 20 hours in platinum crucibles.

Example I A preferred glass composition was prepared and melted from blend ingredients to form the following oxide-based composition to result: Component wt. -SiO2 71.8 Li20 i2.6 K2O 5.1 Al2O3 4.8 B2O3 3.2 P2O5 2.5 The mixture ingredients were weighed and ball milled mixed together. Then the mixture was placed in a platinum crucible and melted them at 1200 to 130,000 for four hours to give a homogeneous, bubble-free Preserve glass. The crucible containing the molten glass was removed from the furnace taken out and from the melt test specimens with a diameter of pulled about 3 mm and quenched in air.

The glass rod was then converted into a glass ceramic, in which one applied the preferred heat treatment of Scheme A in Figure 1. The glass rod was heated to a nucleation temperature of 575 ° C, at this point Maintained temperature for half an hour and then to a crystallization temperature of 860 ° C and held at this temperature again for half an hour the rod was gradually cooled to room temperature.

The glass-ceramic was mainly characterized by a crystalline phase made of lithium disilicate (Li2O # 2SiO2) in a glassy matrix. The product had a A modulus of rupture of about 1960 kg / cm2 (equivalent to 28,000 US pounds per square inch).

Examples II - VIII Following the procedure of Example I, the different glass compositions shown in the following table I melted: Tabel I Composition of the glass ceramics SiO2 Li2O Al2O3 K2O P2O5 B2O3 Example% by weight Mol% wt% mol% wt% mol% wt% mol% wt% mol% wt% Mo II (a) 71.8 67.31 12.6 23.76 5.1 2.82 4.8 2.87 1.65 0.65 3.2 2, III (a) 73.41 57.7 13.91 25.8 4.83 2.62 4.66 2.74 2.92 1.14-IV 79.6 69.4 14.5 26.2 - - 5.7 3.3 2.9 1.1 -V 71, 1 64.3 15.6 23.5 3.9 2.1 6.2 3.6 3.2 1.2 -VI 79.0 69.3 16.0 28.2 1.8 09 2.1 1, 2 1.1 0.4 -VII 78.5 69.5 15.5 27.6 1.8 0.9 2.0 1.1 2.2 0.8 -VIII 77.5 69.9 14.5 26.3 5 , 2 2.8-2.9 1.1 -Note: (a) The compositions of Examples II and III were determined by analyzing the glass.

The compositions were formed into rods that received heat treatments were exposed to induce nucleation and growth.

The temperatures and times of the heat treatments are in the table below II summarized: Table II Heat Treatments Nucleation Growth Tensile Composition Temp. ° C Time (h) Temp. ° C Time (h) Example II 645 1 725 4 645 1 800 4 645 1 830 4 645 1 910 4 645 1 830 168 III 645 1 725 4 645 1 800 4 IV 645 1 725 4 645 1 830 4 645 1 910 4 V 645 1 725 4 645 1 830 4 645 1 910 4 VI 645 1 910 4 645 1 930 2 VII 645 1 830 4 VIII 645 1 830 4 645 1 910 4 It was observed that none of the examined Glass-ceramics are a liquid immiscibility in the amorphous, glass-like state showed. The composition of Example VIII, which is essentially a ternary Composition was, (Al2O3-Li2O-SiO2.) With a small amount of a phosphate / showed only a small amount of lithium metasilicate one Hour at 645 ° C; the main crystalline phase present was lithium dirilicate. Upon further growth heat treatment, only lithium disilicate was present.

The composition of Example IV was also essentially one ternary glass-ceramic with a small addition of phosphate, but contained the composition instead of Al 203 Ii20. This glass ceramic also contained after one hour of treatment at 645 ° C more lithium disilicate than metasilicate. The metasilicate disappeared at Further heat treatment at the growth temperatures of around 750 ° C quickly.

The other essentially quaternary glass ceramics (Al2O3-K2O-Li2O-SiO2) with small amounts of P205 showed considerable lithium metasilicate content with little or no lithium disilicate after one hour at 645 ° C Had kept. The conversion of the lithium disilicate occurred during the growth treatment at temperatures above 75,000. Thus, the glass ceramics produced according to the Examples II, III, VI and VII were obtained after a four hour heat treatment at 83000 lithium disilicate as the predominant crystalline phase with little or no lithium metasilicate.

This fact is important because it can be used to to characterize the microstructure and the crystal content of the glass-ceramic and also the preferred conditions for the crystal growth of the lithium disilicate phase to be determined. The preferred growth of the lithium disilicate phase occurs in spite of the The fact that the nucleation temperature is preferred for the lithium metasilicate phase was. It was found that at temperatures below about 800 ° C only the lithium metasilicate is formed, while the lithium disilicate is preferred at high temperatures crystalline Shape is.

Subsequent investigations including a variation of the growing time confirmed that the most favorable crystal growth conditions for lithium disilicate are given at a temperature of about 850 to 870 ° C. The growing season can can be further shortened if the crystal growth treatment is carried out with a priori gene nucleation heat treatment at a temperature in the range of 550 combined up to 600 ° C.

Claims (6)

Claims 1. Method for producing a glass ceramic, g e -k e n n z e i c h n c t d u r c h the following steps: a) Forming a glass body which essentially ordered from the following components, calculated from the mixture on the oxide basis in% by weight component% by weight Li2O 6 - 20 Al2O3 0 - 10 SiO2 70 - 80 P2O5 0.5-6.0 B2O3 0 - 10 K2O 0 - 6 ZnO ° T 5 b) Heating the glass to a crystal nucleation temperature from 550 to 600 ° C and holding at such temperature for half to one Hour, c) further heating up to a crystallization temperature of 850 to 870 ° C and hold at this temperature for half an hour to an hour, and d) allow to cool at room temperature. 2. The method according to claim 1, d a d u r c h g e -k e n n z e i c h n e t that the glass body essentially consists of the following essential / components in% by weight consists of: 71.8 SiO2, 12.6 Li2O, 5.1 K2O, 4.8 Al2O3 ,. 3.2 B2O3 and 2.5 P2O5. 3. The method according to claim 2, d a d u r c h g e -k e n n z e i c h n e t that the body at a temperature of 575 ° C and a half hour half an hour at a temperature of 860 OC. 4. The product obtained by the process of claim 1. 5. The product obtained by the process of claim 2. 6. The product obtained by the process of claim 3.