DD132332B1 - MACHINABLE GLIMMERIC GLASS CERAMICS AND METHOD OF MANUFACTURING THEM - Google Patents

Description

Field of application of the invention:

The invention relates to machinable micaceous glass ceramics with high bending strength and high temperature resistance, and a process for their preparation. The applications of such ceramics are diverse. Taking into account the specific properties u.a. Fields of application in the following areas: Apparatus construction, machine tool construction, agricultural machinery, chemical industry, light industry, electronics - electrical engineering as well as vacuum and soldering technology ·

Characteristic of the known technical solutions; Machinable glass ceramics have already been described.

In the Federal Republic of Germany OS 2133652, glass ceramics in the following composition range (% by weight ) were investigated: 25-60 SiO ₂ ; 15-35 R ₂ O ^ wherein R ₂ O ₃ from 3-15 ^Б ₂ ° 3 · 5-25 Al ₂ O ^ or 2-20 R ₂ O and R ₃ O from 0-15 Na ₃ O, 0-15 K ₂ O, 0-15 RbpO, 0-20 CspO, 4-25 MgO, and 0-7 Li ₅ O, with LIgO and Li ₂ O being 6-25 percent.

The fluoride concentration is in the range of 4-20 percent. The assurance of machinability can only be guaranteed by the addition of B ₂ O-. For the production of glass ceramics with a holien chemical resist the addition of AIpOo is necessary.

Tetrakiecelic acid fluorinated mica does not contain trivalent cations, such as B ₂ ° 3 ^cdsr Al ₂ O ₃ , which does not provide high chemical resistance. According to the FRG - ОБ 2208236 v / erden tetra-silica fluoromica made of glasses of the following composition range (wt.%):

45-70 SiO ₂ I 8-20 IvIgO; 8-15 UgF ₂ and 5-35 R ₂ O + RO, where R ₂ O is 5-25, and from 0-20 K ₂ O, 0-23 Rb ₂ O, 0-25 Cs ₂ O, and 0-20 RO consists of one or more oxides, 3rO, BaO and CdO.

In the GDR PS 113885 a machinable bare glass ceramic with very good chemical resistance, comparatively low thermal expansion and high temperature resistance is described. The starting glasses have the following composition ( % by weight) Ц-5-75 SiO ₂ J 10-35 Al ₂ O ₃ J 5-25 MgO; 2-10 F; 3-15 Na ₂ O; 0-15 R ₂ O; wherein R ₂ O is the sum of Li ₂ O + K ₂ O or K ₂ O and Na ₂ O.

The erfindun _o cgemäße composition requires relatively high melting temperatures. In the production of these

₂ ser glass ceramic vvird although a high, but 20 kgf / mm not exceeding flexural strength attained.

In the DDR PS 111886, a naturally occurring fluoromica served as a raw material base.

The composition of the glass-ceramics produced therefrom is in the range of 3- SiO ₂ J 15-35 Al ₂ OoJ 5-15 FeOj 5-15 K ₂ Oj 1-15 F; 0-5 Li ₂ O; 0-5 Fe ₂ O ₃ ; 0-5 TiO ₂ 0-3 MnO; 0-5 CaO and 0-5 Na ₂ O.

This type of glass ceramic is particularly

ЗО set of FeO and a spontaneous crystallization behaviors en marked. This results in coarsely crystalline glass ceramics with good machinability but reduced mechanical strength.

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Object of the invention:

The object of the invention is; in the development of a glass-ceramic material that enables the substitution of conventional substances with simultaneous increase in utility properties and ultimately opens up new fields of application.

Explanation of the essence of the invention ; The object of the invention is to provide a machinable gliinmerhaltigen glass ceramic IQ with high bending strength and high temperature resistance and ancestors for their preparation. This object is achieved in that the starting glass has a composition of 35 - 69 SiO ₂ 12 ~ 35 Al ₂ O ₃

3-25 Mgo

2-30 CaO 3 - 25 R ₂ O 2 - 12 F

wherein 3-25 E ₂ O corresponds to the sum of 0-20 K ₂ O and 0-20 NapO and is converted by controlled crystallization into a solid solution containing at least 25% by volume of mica.

The invention is based on the surprising Fe

2 ^> position that in the composition according to the invention by the addition of Kalziunioxid the crystallization maximum up to 15O ⁰ C is shifted to lower temperatures and machinable glass ceramics with high bending strength and high temperature resistance can be obtained

The general formula for mica is X ^ ^ ₁ ^Y 2-3 Z ^ O ₁₀ (OH, F) _2, wherein the gekennzeichz with X ₁ Y, Z Neten cations in the radii-adjusting areas

с о

can differentiate: 2 = 1 to 1.6 Aj У = 0.6 to 0.9 Aj Z = 0.3 to 0.5 A.

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In synthetic mica, the hydroxilions are completely substituted by fluorine ions. From structural considerations it can be concluded that in addition a partial substitution of fluorine by chlorine ions is possible. The calcium ions are incorporated into the X-position of the phlogopite. Ca ions have a relatively high field strength. Therefore, the incorporation of these ions leads to a solidification of the bond in the 001 network plane. This is also reflected in the reduction of the d-values obtained from X-ray examinations.

In the composition of the present invention, the calcium oxide additives promote surface crystallization. Since the phlogopite has a lower expansion value than the starting glass, due to the increased surface crystallization on the surface, a tensile stress is formed in the surface and in the volume of the glass ceramic. This reduces the likelihood of microcracking and increases strength.

This glass ceramic has in volume a myriad of crystals and a uniform surface crystallization.

The size of the mica crystals can control not only the strength but also the mechanical processing properties. The calcium oxide additives also have a viscosity reducing effect. This is of great technological and economic importance, since the temperature can be reduced by 150 to 200 ^° C.

In addition to the alkalis and the SiO 2, the aluminum oxide and fluorine ions are also essential components

The aluminum oxide additives reduce the segregation of the glasses. The specific nature of the nucleation and crystallization mechanism implies that the microplasia delimits the number and size of the mica crystals and thus the properties of the glass-ceramic.

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Therefore, the concentration of the trivalent cation should, based on the oxide basis, at least 12 wt.% Amount. In the GlasphasG, the excretion of synthetic mica is only possible by the substitution of hydroxilions. For this purpose, v / ith a weight concentration of fluorine ions 3 to 5% is preferred.

In the composition of the present invention, chlorine ions and BaO and ZnO may also be introduced to improve the mechanical properties.

For the production of colored glass ceramics, and for the identification of the glass melt or the properties of the glass ceramic, up to a few percent in each case, but not more than 15 percent by weight, of the components CoO, CuO, which have been found to be compatible, can be added to the composition according to the invention. NiO, Fe, FeO, PbO, Cr ₂ Oo, Fe ₂ Oo, B ₂ Oo, As ₂ Oo, Sb ₂ Oo, LiNO _2, TiO _2, SrO _2, P ₂ ^ o ^{or V} 2 O 5 ^will Sesetzt.

In the preparation of the mica-containing glass-ceramics, it must be noted that the crystallization is initiated via the microphase separation.

For the formation of the micro phases and the characteristic crystal phases, theluodynamic and kinetic factors are decisive.

These are in particular the tempering temperature and the tempering.

Preferably, the starting Glaser formation temperature are cooled to room temperature or at least at 5O ⁰ C above the transport and then transferred to a semi-crystalline solution. The transformation temperatures are in the range between 55O ⁰ C to 65O ⁰ C. After heating, the glasses are kept for at least 15 minutes at a temperature between 75O ⁰ C to 110O ⁰ C.

According to the method of the invention, the starting glasses can also be ceramized directly from the melt. This results in coarsely crystalline structures,

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Similarly, a multi-stage ceramization or the slow passage through the said temperature range is possible.

During ceramization, a mica crystal phase is formed which is at least 25% by volume of the total mass of the starting glass. "

For the production of machinable glass ceramics with high bending strength and high temperature resistance, targeted annealing was carried out on the basis of the differential thermal analysis. The glass ceramics thus obtained can be thermally stressed up to 1000 ^° C.

Embodiments;

The invention will be illustrated by a few examples. For this purpose, typical syntheses are listed in Table 1. The corresponding glasses are melted in the temperature range of 14-50 to 158O ° G. Table 2 summarizes the transformation patterns and extension values of some glasses. Table 3 shows, on various syntheses, the influence of the Teiapsrprograuiies on the machinability.

From the investigations carried out, it is apparent that both an optimum ceramization temperature and an optimum ceramization rate should be maintained for the production of the glass ceramic according to the invention. If the ceramicization temperature is too low, the mica crystals will be incomplete. If it is too high, the crystals can partially dissolve again.

The cause of optimal ceramization time is also due to the specific growth mechanism of the mica crystals. Purely a good machinability of the glass ceramic is not only the proportion of phlogopite crystals, but also the llorpho-

2> b logie crucial.

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The possibility of creating a glass ceramic with increased flexural strength and the influence of the Keramisiorungsprosrammes demonstrate the examples of Table 4.

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Claims (4)

claim Λ, machinable micaceous glass-ceramic, in which by controlled crystallization, the glass is converted into a solid solution containing at least 25% by volume of mica, the starting glass components SiO ₂ , Al ₂ CU, MgO, Б ¹ and R ₂ O, characterized in that the starting glass has a composition in wt .-% of (corresponds to the sum of 0-15 and 0-15 N ₀ O) 2, machinable micaceous glass ceramic according to item 1, characterized in that the composition of the starting glass, the following oxides can be added O - 2 Cl
0-8 BaO 3 · machinable mica glass ceramic according to item 1 and 2, characterized in that the molten and preformed glass cooled to room temperature or at least to 5O ⁰ C above Tg and then in the temperature range of 750 - 110O ⁰ C in a glass ceramic based on Pluor -Phlogopitkristallen is transferred. 4. Machinable mica glass ceramic according to item 1 and 2, characterized in that the glass is ceramized directly from the melt at a temperature of 800 - 110O ⁰ C directly for at least 1 hour. Referenced documents: DD-PS 113 885, C 03 C, - 3/22; DE-AS 2133652, C 03 C, 3/22 For this 4 pages tables