AU603903B2 - Glass-ceramic article, process for its production and thermally crystallizable glass - Google Patents

Glass-ceramic article, process for its production and thermally crystallizable glass Download PDF

Info

Publication number
AU603903B2
AU603903B2 AU18140/88A AU1814088A AU603903B2 AU 603903 B2 AU603903 B2 AU 603903B2 AU 18140/88 A AU18140/88 A AU 18140/88A AU 1814088 A AU1814088 A AU 1814088A AU 603903 B2 AU603903 B2 AU 603903B2
Authority
AU
Australia
Prior art keywords
glass
total
cao
ceramic article
mgo
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired
Application number
AU18140/88A
Other versions
AU1814088A (en
Inventor
Andre Andrieu
Marie J. M. Conte
Frederick J. M. Ferry
Jean-Pierre Mazeau
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Corning Glass Works
Original Assignee
Corning Glass Works
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from FR8801288A external-priority patent/FR2626871A1/en
Priority claimed from US07/163,528 external-priority patent/US4786617A/en
Application filed by Corning Glass Works filed Critical Corning Glass Works
Publication of AU1814088A publication Critical patent/AU1814088A/en
Application granted granted Critical
Publication of AU603903B2 publication Critical patent/AU603903B2/en
Anticipated expiration legal-status Critical
Expired legal-status Critical Current

Links

Landscapes

  • Glass Compositions (AREA)

Description

I
AUSTRALIA
Patents Act COMPLETE SPECIFICATION
(ORIGINAL)
Cl;:r Int. Class Application Number: Lodged: Complete Specification Lodged: Accepted: Published: This document contains the Priority amendments made under Section 49 and is correct foi printing.
Related Art: printing.
oo00 0 0 000 1000 0 0000 0.0,,0 APPLICANT'S REFERENCE: Andrieu et al. 8A-1A 0 0 o00 °°ame(s) of Applicant(s): 0 0 Corning Glass Works Address(es) of Applicant(s): 0 00 o00 o Houghton Park, 0°o00 Corning, 0oo. New York, UNITED STATES OF AMERICA.
0 4 4 ,,lAddress for Service is: PHILLIPS ORMONDE FITZPATRICK Patent and Trade Mark Attorneys
S
4 C367 Collins Street Melbourne 3000 AUSTRALIA 4 a0.
Complete Specification for the invention entitled: GLASS-CERAMIC ARTICLE, PROCESS FOR ITS PRODUCTION AND THERMALLY CRYSTALLIZABLE GLASS Our Ref 97162 POF Code: 1602/1602 The following statement is a full description of this invention, including the best method of performing it known to applicant(s): 6003q/l 1 Andrieu-Comte-Ferry-Mazeau 8A-1A-1-17A GLASS-CERAMIC ARTICLE, PROCESS FOR ITS PRODUCTION AND THERMALLY CRYSTALLIZABLE GLASS 0000 0 0 0000 0000 0 0000 000000 0o 5 Background of the Invention 0 00 00 0 o oo oooooo Glass-ceramic articles are traditionally prepared through the closely controlled heat treatment of precursor 0o00 glass articles. On that account, glass-ceramic articles 0 00 °o o 10 are customarily produced by following three general steps: 0oo* first, a vitrifiable batch of a predetermined composition Sis melted; second, this molten mass is cooled to a tempera- 0 00oo o°°o ture at least within the limits of, and normally below, the transformation range and simultaneously made into the form of a glass article having a desired configuration; and, o third, this glass article is exposed to a predetermined 0oo heat treatment in order to cause the generation of crystals in situ. (The transformation range has been defined as the temperature at which a molten material is transformed into an amorphous mass; this temperature in general being estimated as being in the vicinity of the annealing point of a glass.) During the crystallization heat treatment the glass is heated to temperatures above the transformation range of the glass and which approach and ordinarily go beyond its softening point. It is well known that, in these conditions, the viscosity of the glass becomes sufficiently low -2so that the article becomes susceptible to thermal deformation. The severity of this phenomenon obviously increases as the t-emperature approaches the softening point of the glass and goes beyond it.
The crystals developed in a glass-ceramic exhibit a melting point h.i.gher than the softening point of the precursor glass. Consequently, by causing crystallization in situ during the heat treatment of a parent glass article in order to convert it into a glass-ceramic, care must be taken in raising the temperature above the transformation range of the glass to develop sufficient crystallization in order to provide an adequate internal structure to support 0ooo the article, thereby minimizing thermal deformation. One ooo 0ust also realize that the composition of the glass remain- V0 15 ing in the article continually changes as its components 00 00 0 become an integral part of the crystals during the heat 0 o 0o )treatment process. In most cases the viscosity of the o residual glass is greater than that of the parent glass.
Nevertheless, thermal deformation is an ever present 20 problem; particularly with articles having two dimensions 0 .0scin 0 00 which are large but have narrow cross sections, such as o0o00 dinner plates. Such products have required the use of formers or supports during the heat treatment of the 0 00 0 o 0 oo precursor glass article in order to assure the desired geometry in the final product.
Furthermore, the in situ crystallization of a glass article is effected more rapidly and to a greater extent as 00 0 o0 o0 the temperature is raised above the transformation range and into the region of the softening point of the glass.
Consequently, for reasons of industrial economy, it is necessary to raise the temperature of crystallization as rapidly as possible up to a temperature as high as possible.
Such practice obviously increases the risk of thermal deformation of the precursor glass article. Therefore, continued research has been carried out to discover glass compositions capable of rapid in situ crystallization and ii exhibiting only minimum, and preferably practically no, ~1 -3thermal deformation. These researches have been particularly active in the area of tableware articles where a primary objective has been to remove the need for formers to support the articles during the heat treatment of the parent glass bodies.
Summary of the Invention The Applicants were able to achieve that objective through the discovery of a very narrow range of glass compositions in the system K20-Na20-MgO-CaO-SiO2-Al203-F, which compositions can be rapidly crystallized in situ to glass-ceramics wherein potassium fluorrichterite will preferably constitute at least the predominant, if not 15 essentially the sole, crystal phase. In the preferred I products, stringently limited concentrations of BaO and P205 will also be present. The degree of thermal deformation during the crystallization heat treatment of the precursor glass is so little that it is not necessary to use supports to maintain the dimensions of tableware articles, even for table plates having a diameter of about 28 cm. Furthermore, the final glass-ceramic products have a particularly pleasing aesthetic appearance for tableware, exhibiting the slight translucency associated with fine English porcelain. The tableware articles prepared f.,om precursor glass bodies made from the inventive compositions can be heat treated up to complete crystallization by following a program having a duration as short as two hours. It is necessary to apply a glaze on these articles because the glass-ceramic articles do not display a surface gloss and are not durable enough for tableware use. As the low thermal deformation removes the need for formers, the glaze can be applied on the initial glass articles and be fired during the crystallization heat treatment.
-Theemp ition the ao-miond b- jzt-eFei-z to~ boi achirod are composod essentially,- r i-TT-. analygcd in wight percent n th.e id basii, of: iiI i I E -3ao o o 0 0 0 0 0 0 0 o a According to the present invention, there is provided a glass-ceramic article containing potassium fluorrichterite and/or a related fluormica as the predominant crystal phase(s) which, in the form of bars measuring 9cm X Icm X will exhibit sagging during the crystallization heat treatment not greater than 0.75mm over a span of 6.8cm, and which displays such opacity that the diffuse transmittance of a sample of 2.75mm thickness is in the 40-180 range, said glass-ceramic article having a composition essentially free of Li20 and consisting essentially, as expressed in terms of weight percent on the oxide basis, of: SiO 2 61-70 K20 2.5-5.5 Al 2 0 3 2.75-7 Na 2 0+i-K2 <6.8 MgO 11-16 BaO 0-3.5 CaO 4.75-9 P 2 0 5 0-2.5 Na 2 0.5-3 F 2-3.25 The present invention also provides a thermally crystallizable glass wherein it is capable of being crystallized in situ in a period of two hours to form a 20 highly crystalline glass-ceramic article containing potassium fluorrichterite and/or a related fluormica as the predominant crystal phase(s) and which, in the form of bars measuring 9cm X Icm X 5mm, will exhibit sagging during the crystallisation heat treatment not greater than 0.75mm over a span of 6.8cm, said glass-ceramic article having a composition essentially free of Li20 and consisting essentially, as expressed in terms of weight percent on the oxide basis, of: SiO 2 61-70 K20 2.5-5.5 Al203 2.75-7 Na2O+K 2 0 <6.8 MgO 11-16 BaO 0-3.5 CaO 4.75-9 P205 0-2.5 0.5-3 F 2-3.25 2 I 4 making fluorr The present invention further provides a method for a glass-ceramic article containing potassium :ichterita and/or a related fluormica as the -3bpredominant crystal phase(s) and which, in the form of bars measuring 9cm X Icm X 5mm, exhibits sagging during the crystallization heat treatment of not greater than 0.75mm over a span of 6.8cm, and which displays such an opacity that the diffuse transmittance of a sample of 2.75mm thickness is in the 40-180 range, comprising the steps of: melting a vitrifiable batch essentially free of consisting essentially, as expressed in terms of weight percent on the oxide basis, of: SiO 2 61-70 K20 2.5-5.5 Al 2 0 3 2.75-7 Na 2 O0+K 2 0 6.8 MgO 11-16 BaO 0-3.5 CaO 4.75-9 P 2 0 5 0-2.5 0.5-3 F 2-3.25 cooling the resultant melt to a temperature below the transformation range and simultaneously forming a glass article having a desired configuration; and exposing said glass article to a temperature between about 9500-1050 C for a period of time sufficient to .W 20 effect the growth of crystals in situ.
a c a 0 a .o -4- Some As203 and/or Sb203 may be present in an amount up 4gO 11-16 <6.8 CA 4.25. .9 _2 Up to about 2.5% P 2 0- may be included to reduce the tendency of the glass to devitrify and up to 3.5% BaO to reduce its tendencies to devitrify and to opalize.
Some As 203 and/or Sb 2 0 3 may be present in an amount up to 1% in order to perform their usual role as fining agents, while stabilizing the redox state of the glass. Up to about 2% total of such compatible metal oxides as B203, TiO 2 PbO, SrO, ZnO, and ZrO 2 can be included with no substantial adverse effect; the B 2 0 3 level will preferably not exceed 1%.
15 It is possible to utilize conventional colorants for glass, such as Fe 2 0 3 CeO 2 CoO, Cr 2 0 3 CuO, MnO 2 NiO, and
V
2 0 5 in small amounts (t-pically less than 1% total).
S' An amount of Fe 2 0 3 up to 0.5% produces a yellow tint in the glass-ceramic. An amount of 0.15-0.2% yields a color very near to that of English Wedgwood porcelain.
Given that the yellow tint is due to the presence of the Fe 3 ion, it is preferable to include As 2 0 3 and/or Sb 2 0 3 in the batch and an oxidizing ingredient, such as NaNO 3 in order to oxidize the glass and stabilize its redox state.
Laboratory experiments have indicated that when the parent glass bodies are heated, metastable phases are formed above 700 0 C which are transformed at higher temperatures (=950 0 -1050°C) into potassium fluorrichterite (KNaCaMg 5 Si 8
O
22
F
2 as the predominant crystal phase with, perhaps, one or more other crystallographically-related phases, for example, a fluormica.
With compositions of the invention in which elements are borderline with respect to the disclosed composition ranges (for example, containing 0.5% Na20 or 7% A1 2 0 3 the glass-ceramic probably contains, in addition to, or instead of, potassium fluorrichterite, other related phases. These phases have not been studied in detail and are not readily distinguishable from potassium fluorrichterite. Such necessary detailed study has not been deemed mandatory since the phases impart properties to the final product which are closely related to those exhibited when potassium fluorrichterite constitutes the predominant crystal phase.
A significant feature of the disclosed glasses is that they undergo a liquid-liquid phase separation when their molten masses are cooled to a glass body (they form dense opal glasses when cooled slowly). It seems that the occurrence of this phase separation, which leads to a large increase in the viscosity of the glass, is a critical factor in obtaining opaque glass-ceramics exhibiting very little thermal deformation, while applying a short crystallization heat treatment thereto. Hence, it has been visually observed that the thermal deformation of the i parent glass article during the heat treatment decreases in the proportion that it demonstrates a much greater tendency to phase separate. Moreover, the viscosity measurements carried out during the crystallization heat treatment program have indicated that the phase separated glass bodies begin to crystallize at a higher viscosity than those which are practically free of phase separation, and that they retain a higher viscosity during the remainder of the heat treatment. It is believed that this behavior is due to differences in the viscosities of the residual glass matrices.
P205' F, and, to a lesser extent, A1 2 0 3 and SiO 2 favor phase separation. In contrast, alkali metal oxides and, to a lesser extent, alkaline earth metal oxides inhibit it. Therefore, according to the amount of each of these elements, it is possible to adjust the value of the opalization liquidus (phase separation liquidus). Values ranging from about 1050°C to 1400 0 C can be obtained (a viscosity of about 3000 Pa.S and 20 Pa.S, respectively).
An opalization liquidus lower than 1050 0 C leads generally to a high thermal deformation, while a high opalization ~B _h
I!
-6= liquidus makes the glass difficult to form since the opalization leads to a viscosity increase.
Not only has it been observed that the low thermal deformation is related to the phase separation, but also it has been observed that it is a function of the amounts of several critical elements which have to be carefully controlled: Because MgO is a major constituent of the crystalline phases which form during the thermal treatment (especially of fluormicas and potassium fluorrichterite), too small an amount leads to insufficient crystallization which, in turn, results in excessive thermal deformation.
Fluorine favors the desired crystallization: it decreases the temperature (or also increases the viscosity) at which crystallization begins. Therefore, too low an amount, less than leads to a very low viscosity before crystallization begins and, consequently, to a high thermal deformation. However, the presence of fluorine in the residual glass decreases its viscosity. This is the reason a high sag is observed when the level exceeds 3.25% 0 6" BaO seems to stay mainly in the residual glass.
4\ ^0 Consequently, a too high level, viz., higher than leads also to a high thermal deformation.
Vi As mentioned previously, the precursor glass bodies can be subjected to very rapid raises in temperature without undergoing substantial thermal deformation.
Nevertheless, as is the case with other glass-ceramics, crystallization is associatd with densification, so that too rapid raises in temperature can lead to great distortion or even breakage, if there is a thermal gradient in the articles. Such gradients exist, for example, when the thermal treatment is performed in a kiln where the front of the article is heated more rapidly than its rear. The maximum possible speed is, therefore, dependent on the furnace used and on the size and geometry of the articles.
To give an idea, the temperature of the parent glass bodies should generally be raised from about 700 0 C to the maximum u
I
-7temperature (950-10500C) over a period of time of not less than 30 minutes. An exposure period of no greater than minutes at this maximum temperature, typically 10-15 minutes, is sufficient to attain essentially complete crystallization.
The sensitivity of a glass to breakage due to densification thereof is also strongly dependent on its composition: the composition has an influence on the densification speed and the viscosity at which it occurs. The sensitivity of a glass to breakage increases with this speed and this oeo0 viscosity. For example, it has been observed that the ,ooo oeo introduction of Li20, in amounts of about frequently 0 leads to fracture of the body during the crystallization heat treatment. This risk is particularly high in composi- S00 °o°oo 15 tions which exhibit great phase separation. It is believed 0 OOo00 that Li20 favors the crystallization and that breakages are related to a sudden crystallization at temperatures where 0 0 the glasses have a high viscosity.
o 0 On the contrary, it has been observed that K 2 0 widens 0 00 °ooo 20 the temperature range in which densification takes place 0 0 and that it decreases the breakage tendency.
o0.o The optimum maximum temperature of heating treatment is the temperature which gives the maximum opacity for a low thermal sagging. For a given composition, the opacity and the thermal sagging increase together with temperatures in the 950 0 -1050 0 C range. In this range, the optimum maximum temperature is dependent on the composition. In particular, we have observed that it increases when the fluorine level decreases.
Furthermore, the opacity of the final glass-ceramic is strongly dependent upon the amounts of A1 2 0 3 and the alkali metal oxides, and to a lesser extent, the amount of CaO: A level of A1 2 0 3 less than about 2.75% leads to a product of low opacity.
Similarly, an increase in the concentration of alkali metal oxides causes a decrease in opacity such that a total content of 7% yields a body of very low opacity.
i -o8- A too low CaO leve vi,v., loweo than 4.75%, also gives a low opacity.
The inventive glasses exhibit crystallization liquidi in the temperature range of 1180 0 -1260 0 C which correspond, respectively, to viscosities of 300 Pa.S and 80 Pa.S. The viscosity at the crystallization liquidus decreases with the MgO level. This is the reason the level of MgO is limited to 16%. On the other hand, P 2 0 5 which probably stays in the residual glass, increases the viscosity at the crystallization liquidus. Consequently, the preferred o00 glasses contain at least 0.5% P205 Below is specified the preferred area of compositions o which represent the best compromise between the physical properties of the final product and the melting, forming, 15 and crystallization capabilities of the precursor glass.
Like all the glasses disclosed here, they can be transformed through a thermal treatment of less than 2 hours 0 into glass-ceramics displaying an opacity close to Wedgwood o o bone china, and they undergo only a very little thermal 0o o o o 20 deformation during the heat treatment. In addition, they o0 are particularly advantageous from the standpoint of 0 0c manufacturing because their opalization and crystallization liquidi are higher than 100 Pa.S.
SiO 2 63-70 K20 3.5-5 A1 2 0 3 3-4.5 NaO2+K 2 0 >5.25-<6.75 0 MgO 12-14.5 BaO 0.75-2.25 CaO 5.5-7.5 P205 0.5-1.5 1-2.75 F 2-<3 They may also contain the fining agents, compatible metal oxides, and colorants mentioned above in the amounts specified.
Prior Art U. S. Patent No. 4,467,039 describes the production of glass-ceramic articles containing potassium fluorrichterite as the predominant crystal phase. It has been stated that these articles exhibit great toughness, great mechanical
-I
-9strength, and low thermal deformation, and that they are essentially composed, in weight percent, of: SiO 2 50-70 K20 2-12 MgO 8-25 Li 2 0 0-3 CaO 4-15 A1 2 0 3 0-7 2-9 F 3-8 Although the broad ranges of components disclosed overlap those of the present invention, there was n recognition of a narrow range of compositions which can be oooo, crystallized in situ very rapidly with nearly no thermal 0 0 a 0 0 0o0 .o00 deformation. In fact, rates of temperature increases of 0o 200 0 C/hour to the crystallization temperature and minimum 0o exposure periods of 30 minutes at the crystallization 0 00 °a00' 15 temperature are mentioned. In contrast, the temperature of the glass bodies of the present invention can be raised at rates up to 600°C/hour and these bodies do not require more than 15 minutes at the crystallization temperature to '0 arrive at essentially complete crystallization. No composi- .0 20 tion of the working examples furnished in this patent is within the limits of the products of the present invention.
U. S. Patent No. 4,608,348 describes the preparation of glass-ceramic articles which demonstrate great toughness and very low thermal deformation, which contain potassium fluorrichterite as the predominant crystal phase, but which also contain substantial quantities of cristobalite.
Compositions providing such products are composed essentially, in weight percent, of: SiO 2 65-69 Na 2 0 1.5-3.3 Al203 0.75-3.5 K20 4.2-6.0 MgO 13.5-17.5 BaO 0-2.5 CaO 3-4.8 P205 0-2.5 0.5-2.0 F 3.3-5.5 The CaO content is lower than that required in the compositions of the present invention; the F content is higher; and Li 2 0 is a required component. Furthermore, substantial quantities of cristobalite are desired in the glass-ceramic, whereas the presence of cristobalite is neither required nor desired in the products of the present invention, Description of Preferred Embodiments Table I records numerous glass compositions illustrating the compositional parameters of the present invention. The fluorine and oxide contents, except SiO 2 have 0°P°0 been analyzed in terms of weight percent in the glass. The 0. SiO 2 content was calculated from the batch materials.
Since it is not known with which of the cations the fluorine is combined, this last is simply indicated in the table in 15 terms of fluorine, conforming to current practice in the material analysis of glass. The actual ingredients entering into the batch for the preparation of the glass may consist of any materials, either oxides or other compounds, which, 'when melted together, will be transformed into the desired oxides in the correct proportions.
About 2500 grams of the batch ingredients were mixed, placed in platinum crucibles, and melted for four hours at 1500°C. The meltc were formed into bars of 1 cm thickness and then transferred to an annealer operating at 6000°C 2S Whereas the compositions given as examples in Table I only reflect studies conducted in a laboratory, it will be realized that the compositions of the examples conforming with the compositional parameters of the invention could be melted and fashioned by means of conventional industrial equipment for melting and forming glass on a large scale.
In order to determine the resistance of each composition to thermal deformation, bars measuring 9 cm long, 1 cm wide, and 5 mm thick were cut from the annealed glass bars.
These bars were then place on a ceramic support having a span gap of 6.8 cm and introduced into an electricallyheated furnace operating at 720 0 C. The temperature was then raised to 800 0 C at a rate of about 5°C/minute; the i_ -11temperature was then raised to 1000 0 C at a rate of about 16°C/minute; this temperature was maintained for 15 m. .utes; then the electric current to the furnace was cut off and the furnace left to cool to 800 0 C at a proper rate (about 10°C/minute); and thereafter the samples were withdrawn from the furnace.
Table II furnishes the results of various measurements conducted on the crystallized samples. For example: The degree of sag (Sag) suffered by the 5 mm thick bars was determined. Experience of thermal deformation suffered by table plates of 28 cm diameter has shown that a thermal sag of 0.75 mm in the above test is the maximum that can be tolerated in order to permit the crystallization in situ of these plates without the use of formers.
The opacity was evaluated by measuring the diffuse i transmission of crystallized samples. Opacity is inversely proportional to the diffuse transmittance. The measurements have been made on samples having a thickness of 2.75 mm, a diameter of 32 mm and having their two faces polished. A small part of one face of the sample (6 mm diameter) is illuminated with a filament lamp. The transmitted light is recorded on a larger surface detector (20 mm diameter) through a ground glass diffuser which is applied against the opposite face of the sample. The diffuse transmission (Diff.) values indicated in Table II reflect an arbitrary scale. On this scale English Wedgwood bone china exhibits diffuse transmissions included in the interval of 90-110, the Limoges porcelains have diffuse transmissions lower than 10, the opal glass of trademark "Arcopal Table" has a diffuse transmission of 250 and the laminated opal glass of trademark "Corelle" a diffuse transmission of 200. It has jbeen estimated that in order for tableware articles to look like English bone china, their diffuse transmission must be in the 40-180 range and preferably in the 50-160 range.
Moduli of rupture (MOR) were measured on abraded I i samples using techniques conventional in the art. The values are indicated in terms of MPa.
r L -i i -12- The opalization liquidus temperature (Opal) in OC, the phase separation liquidus, was estimated by following the amount of light reflected by the glass during cooling of the melt. The viscosity (Vis.) of the glass, at that temperature, reported in terms of Pa.S, was determined from a viscosity curve measured on the melt in the convention manner.
The crystallization liquidus temperature (Cryst.) in OC was determined by conventional methods; the samples were subjected to isothermal treatments, then observed with an optical microscope. Again, the viscosity of the glass in Pa.S at that temperature was determined from a conventional viscosity curve measured on the glass.
Examples 1-10 are encompassed within the preferred composition region. in addition to a sag less than or equal to 0.75 mm, they display a diffuse transmission in Sthe 50-160 range and viscosities at the opalization and I crystallization liquidi higher than 100 Pa.S. Moreover, these glasses are the easiest to crystallize.
Example 7 is the most preferred: it displays the best compromise between all the properties. Examples 1, 7, 8, 9, and 10 closely approximate the color of English Wedgwood bone china. For example, a glass having the composition of Example 1 and having undergone the heat treatment described above displayed the color coordinates x=0.3135, y=0.3233, and Y=86%, (Illuminant As a measure of comparison, Wedgwood bone china exhibited the color coordinates x=0.3139, y=0.3232, and Y=86%. Measurements have been conducted through diffuse reflection with a white background.
Examples 19-22 are located outside the specified limits. To be precise: The Al 2 0 3 content in Example 19 is too low. The fluorine level of Example 20 is too high. Each of those compositions exhibits excessive thermal sagging and a strong diffuse transmission.
L _e j -13- The total Na 2 O+K 2 0 content is too high in Example 21, since the sum of Na 2 O+K 2 0 must be less than The amount of Na 2 O0 in Example 22 is excessive. Those two compositions demonstrate strong diffuse transmission.
Table I Sio 2 Al 203 IVgO CaO Na 20 BaO 205 As 203 Fe 2 03
F
Na 20+K 20 1 66.0 3.6 13.7 6.2 2.3 4.2 1.0 1.1 0.25 0.18 2.6 6.5 8 65.6 3.7 13.7 6.4 1.0 4.9 1.8 0.29 0.15 2.5 5.9 2 66.9 3.5 13.4 6.4 2.2 4.1 1.0 1.0 2.5 6.3 9 67. 3 3.8 13.0 5.7 1.5 4.3 1.6 0.9 0.26 0.17 2.5 5 8 3 65.9 3.7 13.9 6.4 2.5 3.8 1.0 1.2 2.7 6.3 10 66.6 3.6 13.2 6.5 2.0 4.1 1.5 0.6 0.27 0.16 2.5 6.1 4 66.7 4.3 13.5 6.4 2.2 3.6 0.9 0.7 2.9 5.8.
11 66.7 3.8 13.8 5.4 2.3 4.2 1. 1 1.2 2.6 6.5 5 6 7 65.2 3.8 14.3 6.3 2.4 4.3 1.0 1.2 2.6 6.7 65 3 13 6 2 4 1 1 .5 67.0 .7 3.7 .6 13.0 .9 6.3 .3 .3 4.3 .0 1.6 .2 Q.9 0.25 0.17 .6 2.4 .6 5.8 2 6 S3 Al 203 MgO CaO Na 2
Q
Bao As 2 0 3 Fe 2 03
F
Na 20+K 20 12 66.7 3.5 13.8 6.8 1.9 3.1 3.0 5.0 13 66.6 3.9 13.6 6. 8 2.3 4.1 14 68 .0 13.3 6.4 2.2 3.4 2.6 6.4 5.6
I',
n -14- Table I (con't.) Sio 2 A1 2 0 3 MgO CaO Na 2 O0 BaO 20 As 2 O0 3 Fe 203
F
20 16 17 18 67.1 66.2. 65.0 64.6 5.0 3.6 5.0 3.4 13.3 14.6 13.6 14.6 6.4 5.0 6.5 7.1 2.2 2.3 2.2 2.3 3.4 3.5 4.1 3.9 0.9 0.9 1.0 0.9 2.1 1.0 1.5 3.0 3.25 2.7 3.0 5.6 5.8 6.3 6.2 19 20 67.8 67.0 2.6 3.4 13.6 13.3 6.2 6.2 2.2 2.1 4.1 4.1 0.9 0.9 1.0 1.0 2.7 3.5 6.3 6.2 21 65.4 3.7 13.8 6.3 2.7 4.3 1.0 1.2 2.7 7.0 22 65.9 3.7 13.5 6.4 3.2 P 0.9 1.4 2.6 6.7 7 0.25 104 Sag Duff.
MOR
opal Temp.
Vis.
Cryst.
Temp.
Vis.
1 0.25 130 2 0.25 153 83 1160 600 1220 200 Table Il 3 4 0.25 0.25 150 109 83 5 0.25 145 6 0.5 141 1220 220 1240 160 1210 220 1240 160 Table~ 11 (con t t.) 8 9 10 11 12 13 14 Sag 0.25 0.5 0.5 0.5 0.25 0.25 0.25 Diff. 95 106 127 180 60 138 150 MOR -76 Opal Temp. 1230 1200 1380 1200 Vis. 30 240 Cryst.
Temp. 1220 1220 08 0 13 16 17 18 19 20 21 22 Sag 0.5 0.25 0.25 0.25 1.0 3.0 0.75 o 0 NOR 76 83 C0O0'~ Opal Temp. 1200 1240 1140 1280 00 Vis. 280 140 90 00 Cryst.
00 20 Temp. 1240 1240 1220 000Vis 160 140 720 06

Claims (4)

1. A glass-ceramic article containing potassium fluorrichterite and/or a related fluormica as the predominant crystal phase(s) which, in the form of bars measuring 9cm X Icm X 5mm, will exhibit sagging during the crystallization heat treatment not greater than 0.75mm over a span of 6.8cm, and which displays such opacity that the diffuse transmittance of a sample of 2.75mm thickness is in the 40-180 range, said glass-ceramic article having a composition essentially free of Li20 and consisting essentially, as expressed in terms of weight percent on the oxide basis, of: SiO 2
61-70 K 2 0 2.5-5.5 Al203 2.75-7 Na20+K 2 0 <6.8 MgO 11-16 BaO 0-3.5 CaO 4.75-9 P205 0-2.5 Na 0 0.5-3 F 2-3.25 2. A glass-ceramic article according to claim 1 wherein it consists essentially in terms of weight percent of: SiO 2
63-70 K20 3.5-5 Al203 3-4.5 Na20+K20 >5.25-<6.75 MgO 12-14.5 BaO 0.75-2.25 CaO 5.5-7.5 P205 0.5-1.5 Na20 1-2.75 G F 2-<3 0000 o0 o S 0 00oo0o 0 o o 0 0 0 00 0 0 0o 04 04*' 3. A glass-ceramic article according to claim 1 or 2 wherein it also contains up to 4 wt.% total of at least one member in the indicated proportion of the following groups consisting of up to 1% total of Fe 2 0 3 CeO 2 CoO, Cr 2 0 3 CuO, MnO 2 NiO, and V 2 0 5 up to 2% total of B203, PbO, SrO, ZnO, TiO 2 and ZrO 2 and up to 1% total of As203 and Sb 2 0 3 4. A glass-ceramic article according to any one of claims -17- 1 to 3 wherein it is a tableware article. A thermally crystallizable glass capable of being crystallized in situ in a period of two hours to form a highly crystalline glass-ceramic article containing potassium fluorrichterite and/or a related fluormica as the predominant crystal phase(s) and which, in the form of bars measuring 9cm X Icm X 5mm, will exhibit sagging during the crystallisation heat treatment not greater than 0.75mm over a span of 6.8cm, said glass-ceramic article having a composition essentially free of Li20 and consisting essentially, as expressed in terms of weight percent on the oxide basis, of: SiO 2 61-70 K20 2.5-5.5 Al203 2.75-7 Na2O+K20 <6.8 MgO 11-16 BaO 0-3.5 000 CaO 4.75-9 P205 0-2.5 S. Na 2 0 0.5-3 F 2-3.25 o o 6. A thermally crystallizable glass according to claim 0 0 1 wherein said glass consists essentially in terms of weight percent of: SiO 2 63-70 K20 3.5-5 Al203 3-4.5 Na20+K 2 0 >5.25-<6.75 MgO 12-14.5 BaO 0.75-2.25 CaO 5.5-7.5 P205 0.5-1.5 1-2.75 F 2-<3 7. A thermally crystallizable glass according to claim or 6 wherein said glass displays a viscosity at the opalization liquidus higher than 100 Pa.S and a viscosity at the crystallization liquidus higher than 100 Pa.S. 8. A thermally crystallizable glass according to any one of claims 5 to 7 wherein it also contains up to 4 wt.% total of at least one member in the indicated proportion of the -I -18- following groups consisting of up to 1% total of Fe 2 0 3 CeO 2 CoO, Cr 2 0 3 CuO, MnO 2 NiO, and V 2 0 5 up to 2% total of B 2 0 3 PbO, SrO, ZnO, TiO 2 and ZrO 2 and up to 1% total of As203 and Sb203. 9. A method for making a glass-ceramic article containing potassium fluorrichterite and/or a related fluormica as the predominant crystal phase(s) and which, in the form of bars measuring 9cm X Icm X 5mm, exhibits sagging during the crystallization heat treatment of not greater than 0.75mm over a span of 6.8cm, and which displays such an opacity that the diffuse transmittance of a sample of 2.75mm thickness is in the 40-180 range, comprising the steps of: melting a vitrifiable batch essentially free of Li 20 consisting essentially, as expressed in terms of weight percent on the oxide basis, of: 000. SiO 2 61-70 K20 2.5-5.5 Al203 2.75-7 Na20+K 2 0 <6.8 :aa 23 2 2 MgO 11-16 BaO 0-3.5 CaO 4.75-9 P205 0-2.5 °0 20 Na20 0.5-3 F 2-3.25 0 6 cooling the resultant melt to a temperature below the 0000a0 transformation range and simultaneously forming a glass article having a desired configuration; and exposing said glass article to a temperature between
9500-1050 0 C for a period of time sufficient to effect 0t the growth of crystals in situ. Sa t 0 a o i a c 0 1 0 4 d o 00 10. A method according to claim 9 wherein said glass-ceramic consists essentially in terms of weight percent of: 30 SiO 2 63-70 K 2 0 3- Al203 3-4.5 Na 2 0+K20 >5.25-<6.75 MgO 12-14.5 BaO 0.75- 2.25 CaO 5.5-7.5 P205 0.5- 1-2.75 F 2-<3 i! -19- 11. A method according to claim 9 or 10, wherein the vitrifiable batch also contains a small quantity of an oxidizing agent. 12. A method according to any one of claims 9 to 11 wherein said period of exposure to a temperature between 950°-1050°C is at most 30 minutes. 13. A method according to any one of claims 9 to 12 wherein the vitrifiable batch also contains up to 4 wt.% total of at least one member in the indicated proportion selected from the following groups consisting of up to 1% total of Fe20 3 CeO2, CoO, Cr20 3 CuO, MnO 2 NiO, and V 2 0 5 up to 2% total of B 2 0 3 PbO, SrO, ZnO, TiO 2 and ZrO 2 and up to 1% total of As 2 0 3 and Sb 203 14. An article according to claim 1, substantially as herein before described with reference to the Examples. -a-r-tiol. according to claim 5, substantially as herein before described with reference to the Examples. 16. A method according to claim 9, substantially as herein before described with reference to the Examples. DATED: 20 MARCH, 1990 PHILLIPS ORMONDE FITZPATRICK Attorneys For: CORNING GLASS WORKS t fAll W
AU18140/88A 1988-02-04 1988-06-20 Glass-ceramic article, process for its production and thermally crystallizable glass Expired AU603903B2 (en)

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
FR8801288 1988-02-04
FR8801288A FR2626871A1 (en) 1988-02-04 1988-02-04 VITROCERAMIC ARTICLE, PROCESS FOR MANUFACTURING THE SAME AND THERMALLY CRYSTALLIZABLE GLASS
US07/163,528 US4786617A (en) 1986-10-13 1988-03-03 Glass-ceramic article, process for its production and thermally crystallizable glass
US163528 1988-03-03

Publications (2)

Publication Number Publication Date
AU1814088A AU1814088A (en) 1989-08-10
AU603903B2 true AU603903B2 (en) 1990-11-29

Family

ID=26226477

Family Applications (1)

Application Number Title Priority Date Filing Date
AU18140/88A Expired AU603903B2 (en) 1988-02-04 1988-06-20 Glass-ceramic article, process for its production and thermally crystallizable glass

Country Status (4)

Country Link
AU (1) AU603903B2 (en)
BR (1) BR8900432A (en)
CA (1) CA1299590C (en)
DE (1) DE3861768D1 (en)

Families Citing this family (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN115784616A (en) * 2022-11-15 2023-03-14 常熟佳合显示科技有限公司 MAS microcrystalline glass and preparation method thereof

Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP0126572A1 (en) * 1983-05-09 1984-11-28 Corning Glass Works Potassium fluorrichterite glass-ceramic and method
AU6446086A (en) * 1985-11-04 1987-05-07 Corning Glass Works Glass-ceramics containing cristobalite and potassium fluorrichterite
AU7970787A (en) * 1986-10-13 1988-04-14 Corning Glass Works Glass-ceramic

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP0126572A1 (en) * 1983-05-09 1984-11-28 Corning Glass Works Potassium fluorrichterite glass-ceramic and method
AU6446086A (en) * 1985-11-04 1987-05-07 Corning Glass Works Glass-ceramics containing cristobalite and potassium fluorrichterite
AU7970787A (en) * 1986-10-13 1988-04-14 Corning Glass Works Glass-ceramic

Also Published As

Publication number Publication date
BR8900432A (en) 1989-10-31
CA1299590C (en) 1992-04-28
AU1814088A (en) 1989-08-10
DE3861768D1 (en) 1991-03-14

Similar Documents

Publication Publication Date Title
EP0587979B1 (en) Low expansing transparent crystallized glass-ceramic
EP0437228B2 (en) Thermally crystallizable glass, glass-ceramic made therefrom, and method of making same
JP7458388B2 (en) Transparent β-quartz glass ceramic with low lithium content
KR101476862B1 (en) Transparent colorless low-titania beta-quartz glass-ceramic material
KR101848517B1 (en) Beta-quartz glass ceramics and related precursor glasses
US3490984A (en) Art of producing high-strength surface-crystallized,glass bodies
US5591682A (en) Low expansion transparent glass-ceramic
US8143179B2 (en) Transparent, colorless titania-free beta-quartz glass-ceramic
EP0997445B1 (en) Low expansion glass-ceramics
US7476633B2 (en) β-spodumene glass-ceramic materials and process for making the same
US4018612A (en) Transparent beta-quartz glass-ceramics
JP2000247681A (en) SEMITRANSPARENT OR OPAQUE GLASS-CERAMIC HAVING beta-QUARTZ SOLID SOLUTION AS MAIN CRYSTALLINE PHASE AND ITS USE
JP2018523624A (en) Transparent, essentially colorless, tin clarified LAS glass ceramic with improved microstructure and thermal expansion
JP4471075B2 (en) Mineral glass that can be ceramicized, preparation of glass-ceramic products, and products
JPS63265840A (en) Optical glass
US4786617A (en) Glass-ceramic article, process for its production and thermally crystallizable glass
KR20200033907A (en) Low titanium content, tin-purified white, milky white or opaque beta-spodumene glass-ceramic
JP4287119B2 (en) Glass ceramic and method for producing the same
EP0326735B1 (en) Glass-ceramic article, process for its production and thermally crystallizable glass
AU603903B2 (en) Glass-ceramic article, process for its production and thermally crystallizable glass
US3528828A (en) Glass,ceramics,and method
US3499773A (en) Semicrystalline ceramic bodies,and method
CA1277339C (en) Glass-ceramic article process for its production and thermally crystallizable glass
US5385871A (en) Fluorine-containing lead- and cadmium-free glazes
JPS63103842A (en) Glass ceramic product, manufacture and thermal crystalline glass