DD153108A1 - FLUORO-PHOENOPHONE GLASS CERAMICS WITH BEST MACHINERYABILITY - Google Patents

Abstract

The invention relates to fluorophlogopite-containing glass ceramic with the best machinability. The aim of the invention is to significantly improve the machinability of micaceous glass-ceramics and to develop new material properties for the material. The object of the invention is to develop a glass ceramic which is distinguished by the best machinability and good thermal, chemical and mechanical properties. The object is achieved according to the invention in that a base glass of the composition in mass% 34-60 SiO 2, 21-36 Al 2 + 3, 8-17 MgO, 5-12 R 2, 1-7 F & under the condition that R & ind2! O represents the sum of 0-8 Na & ind2! O and 0-6 K & ind2! O, and under the conditions that for mass concentrations of 1-2.5 mass% SiO &sub2;! / (MgO + Al & ind2 2, 1-1.5 and for F & concentrations of 2.5-7% by mass the mass ratio SiO & ind2! / (MgO + Al & ind2! O & ind3!) Is approx. 1.5-0, 7, after melting and thermal treatment, is converted into a solid solution with blotched fluorophlogopite crystals in a spherical-lamellar arrangement. Possible applications are e.g. in Geraetebau and chemical plant construction.

Description

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Gain the invention

Fluorophenol-containing glass ceramic with excellent machinability

Anlegegebie t of the invention

The invention relates to fluorophorophen-containing glass ceramic with excellent machinability and good thermal, mechanical and chemical properties. The glass ceramic according to the invention can be used as a substitution material for metals with new and better properties in chemical plant construction, mechanical engineering, equipment construction and in electronics electronics.

Characterization; the known tech nical solutions gene

Machinable glass-ceramics are known «This type of material has been extensively studied« In particular, the crystallization behavior of glasses which have been converted into machinable glass-ceramics by targeted thermal treatment was in the interest of the research «The sedimentation of glimmering crystals is in most cases one , Basic requirement for machinability of the glass-ceramics · The mica have the general formula X _n ^ ^ ΐ ^^^, Ζ, Ο ^ gFg, v / if the X-positions are given by ions with the radii 1-1.6 S, Y with ions of radii 0.6-0, 9 X and Z are occupied with ions of radii 0.3-0.5 l ·

In DT-AS 2,133,652, the precipitation of potassium triumph with MIg ₃ AlSi ₃ O ₁₀ P ₂ , borophlogopite KMgBSi ₃ O ₁₀ P ₂ and aluminum borophlogopite in glasses of the system SiO ₂ -B ₂ O ₃ -Al ₂ O ₃ - MgO-K ₂ OP "with additions of Na ₂ O, Rb ₂ Oj Cs ₂ O, Li ₂ O described. As remarkable result it was found that without the presence of B ₉ Oo a machining of these glass ceramics is not possible of B ₂ O, by BaO and SrO and ensuring machinability as described in DT-OS 2 * 224,990, the chemical properties of the glass-ceramic are significantly degraded. As shown in DT-OS 2 _e 208 "236 a complete substitution of trivalent ions in the mica lattice .. The generated in the glass ceramic tetraacetic acid mica of the system SiO ₂ -MgO RgO (alkali oxides) · = RO (alkaline earth oxides) also allow machinability of these materials »DS-PS 132.332 and DS »PS 113.88 5 describe machinable glass-ceramics and processes for their preparation in the system SiO ₂ -Al ₂ O ₃ -MgO-PR ₂ O with possible presence of additives. The main crystal phase of these glass-ceramics are pluorphlogopite crystals. The flake-form phlogopite crystals in DS-PS 132.332 and DE-PS 113 * 885 are like the sheet silicates in DT-AS 2.133 * 652, DT-OS 2.224.990 and DT-OS 2.208.236 glass ceramics embedded in a random Kartenhausälinliche arrangement embedded in the Glasmatris. Due to the interlocking of the crystals a RiJB propagation is guaranteed and the machinability of the glass ceramics is possible.

Phlogopites other than this map-mouse morphology are described in U.S. Patent 3,325,265. The basic glass specified there has the composition 6 - 13 % K ₂ O, BaO and / or. SrO, 25 - 33 %

MgO, 12-15 % Al ₂ O ₃ , 8.5-9.5 % B ₂ O ₃ , 40-52 % SiO ₂ , 4.5-16 % P Ma%. Upon instantaneous thermal treatment of the cooled melt, spherical clusters of pluorphlogopite crystals are formed. However, since these crystal clusters do not crosslink with each other, the machining of these glass-ceramics is very poor, i. H". almost impossible. However, it is known that in order to achieve a good machinability of glass ceramics exclusively platelet-shaped mica crystals in card house arrangement are necessary. However, due to this crystal arrangement, substantially no better machinability of the glass-ceramics has been achieved. This Hangel should be overcome in the glass-ceramic according to the invention.

Object of the invention

The object of the invention is, while avoiding the disadvantages of the prior art, to significantly improve the machinability of micaceous glass ceramics and to develop new material properties for the material.

Explanation 0.8S ₁ essence of the invention

Job de ^ invention is to develop a ceramic glass, which is characterized by best machinability and good thermal, chemical and mechanical properties.

It has been found that the machine machinabilities achieved so far of micaceous glass-ceramics improved significantly, the material new own shafts can be developed. This is an enormous port step compared to the previously known state of the art.

The object of the invention is inventively achieved in that a _$ base glass of the composition in wt%

SiO ₂ = 34 - 60 0, = 21-36

MgO 8th - 17 R ₂ O = 5 - 12 P " - 1 - 7

under the condition that R ₂ ^{0 &} ^ ^{Q sum} from 0-8 Ma. -% Ua ₂ O and 0-6 Ma .-% K ₂ O and under the conditions that for F "" - concentrations of 1-2.5 Ma .-%, the mass ratio SiO ₂ / (MgO + Al ₂ O ., "ca" 2.1 - 1.5 and for F ~~ concentrations of 2.5 - 7 wt .-%, the mass ratio Si0 ₂ / (Mg0 -4 * AlgOo) about 1.5 - 0.7 is thermally treated after melting "

Erfindungsgeniäß is the starting glass after melting at about 1420 * C ⁰ - 1550 ⁰ C cooled below the CCransfonaationstemperatur and then crystallized at the devitrification temperature in situ or directly from the melt in the thermally treated Entglasungsbereich "

It was surprisingly found that the phlogopit «similar crystals do not arise in a random kratenhausähnlichen arrangement, but that the leaflets * shaped mica crystals in a spherical lamellar arrangement in the manner of a" cabbage "go over. At the conclusion of the ceramization process, the phlogopite-like crystals are connected to each other. Depending on the composition and thermal treatment of the glass, άβχ% voluinenanteil of crystal phase can be up to 70 % and more.

The results of the X-ray diffraction and slektronenbeugungsanaiyse showed that the excreted layer silicates are still crystals which crystallize in phlogopite lattice but have a slightly altered crystal composition. Compared to the previously described phlogopites, the crystals which precipitate here have precipitation

a low Mg / Al "* ^r ~ over.

A profound understanding of the kinetics and control of microstructure formation processes is allowed

223 f25 -

with relatively small changes in the compositions of known starting glasses to achieve this enormous effect in the crystal excretion and the resulting Glaekeramikeigenschaften. Up to 14% by weight of the following oxides can be added to the basic glass according to the invention without the kinetics of the excretion of the mica crystals changing in their morphology: CaO, BaO, PeO, ΡθρΟ ^ and

According to the invention, the glass ceramic is produced in the manner that the molten glass is cooled below the transformation temperature and molded into an article or poured directly from the melt into a mold, the thermal range being in the range 750 ^° C.-1000 ^° C. Treatment is done. If temperatures for heat treatment of about 1000 - 1200 ⁰ C selected, not the formation of the glass-ceramic according to the invention, but the phlogopite glass ceramic with the already known card house arrangement of the crystals.

The Haitezeit for thermal treatment is in the lower temperature range 25 - 100 h and in the top about 1 »5 h. After completion of the crystallization, the samples sit at a temperature of about 3 to 4 K min., Due to the composition according to the invention, the segregation tendency of the starting glasses and thus the nucleation density for the formation of the primary crystal phases in the glass are relatively low.

Nonetheless, it is surprising that the primary crystal phases of the humit series customary in phlogopite glass ceramics do not occur in the glass ceramic according to the invention. Mica was always detected as the prismar phase with the aid of X-ray diffraction and electron diffraction investigations and microscopic analyzes. This fact is obviously an essential basis for the formation of the leaflet-shaped phlogopite crystals in a spherical-lamellar arrangement. In the glass ceramic according to the invention, the mica crystals have a length of 25 at a high aspect ratio.

100yum. However, the crystals are connected to each other in a very optimal manner and therefore differ substantially from the known phlogopite crystals, not only in their composition but also in their morphology. Since the crystals in the glass-ceramic according to the invention have grown together in an optimum manner, machinability of the glass-sera material is Surprisingly, it is 4 to 5 times better than phlogopite glass ceramics in which the crystals have a house of cards arrangement. Despite the size of the crystals, the flexural strength of the glass ceramic has values of 140-210 MPa and the mean surface roughness of 0j5-1 5y indicate very good mechanical properties of the glass-ceramic according to the invention. The chemical resistance and the thermal properties are also comparatively good.

The concentrations given in Table 1 provide a more detailed overview of the compositions according to the invention of the starting glasses and glass ceramics. In this case, the exemplary embodiments 1-7 _{S show} that SiO ₂ -Al ₂ Oo-MgO-Na _? 0-Kp0-P "" the glass ceramic according to the invention can be produced. Examples 8-11 show that the additives BaO, CaO, IeO, Pe ₂ Oo, P ₃ O _{5 are} also possible.

The accompanying drawing shows the leaflet-shaped phlogopite crystals in a spherical-lamellar arrangement in the glass-ceramic according to the invention. In Table 2, the machinability of the glass-ceramic according to the invention fully corresponds to the intended target direction. Also the chemical properties shown in Table 3 and the mechanical parameters of the flexural strength, which are 140 - 210 LIPa, and the thermal properties with a linear thermal expansion coefficient of 52 - 75.1O ~ K ~ ¹ fulfill the task. In addition, the glass-ceramics have a good temperature change resistance and temperature stability.

Table 1

SiO ₂ Al ₂ O ₃ MgO P "*

ITa ₂ OK ₂ O BaO

1 2 3 4 5 6 7 8;

59.4 38.5 51.1 43.0 41.8 48.4 49.3 48.7

21.7 36.0 24.0 30.3 30.2 29.1 27.5 22.9

8.6 15.2 10.1 13.1 17.1 12.6 11.8 9.6 1.8 6.5 3.5 4.9 4.4 2.7 2.7 3.3

3.7 - 5.6 4.1 8.7 3.2 3.2 5.3 5.0 5.8 6.0 4.9 - 4.3 5.3 5.7

- - 6.4

9 10 11 SiO ₂ 34.1 52.5 45.4 Al ₂ O ₃ 31.8 19.1 25.3 MgO 13.5 7.2 10.8 P " 5.7 2.5 3.4 Ka ₂ O 1.4 3.2 2.9 K ₂ O 3.7 4.1 4.9 CaO 12.1 - - PaO 3.9 - Pe ₂ O ₃ - 9.8 - P ₂ O ₅ - - 8.6

Table '2 Glass Ur _e

thermal treatment machinability ⁰ C; H

1 960 " 5 Well 62 3 4 6 7 8 2 980 • 1 very well 3 960 • 1 excellent 1 1-2 1-2 1-2 1-2 4 980 t 4 very well 2 2-3 2-3 2 2-3 5 960 C 4 Well 6 960 • f 2 excellent 60-69 68-75 - 65-73 63- 7 980 C Ϊ 2 excellent 0 7 750 * I 50 very well 8th · 980 * f 5 good- 9 960 • t 4 Well 10 940 t 4 very well 11 980 Ϊ 2 Well - 180 160 Table 3 property Experimental values of glass-ceramics 1 hadrolytische class 1 lye class 1 linear ther mixed alis = 52- strain coefficients for 10Q ~ 400 ° C in 1CT ⁷ K * ^"1 Bending " strength 21 in MPa

Claims (3)

Pluorphlogopithaltige glass ceramic with best machinability characterized in that a starting glass of the composition in Ma .-% on the condition that EoO is the sum of O - 8 Ma « -% ₂ O and 0-6 Ma _e ~% K _? 0 and under the conditions that for P "concentrations of 1 ~ 2 _$ 5 Ma. ~%, The mass ratio SiO ₂ Z (MgO-I-Al ₂ Oo) about 2.1 to 1.5 and for ^ concentrations of 2 _$ 5 - 7, the mass ratio SiO ₂ Z (LOgO-1-Al ₂ O-,) is approximately 1.5 to 0.7, which is thermally treated after melting. 2 characterized in that the basic components of the following components: BaO, CaO, PeO, Fe ₂ O ^ and P ₂ 0 _r can be added from 0-14% by mass « 4. Pluorphlogopithaltige glass-ceramic according to item 1 ₅ 2 and 2 ". Pluorphlogopithaltige glass-ceramic according to item 1, characterized in that the melted base glass is cooled below the transformation temperature and molded into an article or gegosssn directly from the melt into a Forin, wherein in the range 750 ⁰ C - 1000 ⁰ G, the thermal treatment takes 1-100 hours , 3 "Pluorphlogopithaltiga glass ceramic according to item 1 and 3, characterized in that the precipitated phlogopite crystals Laiaellenfönrdg to Kugelpaketen zusamme nge superimposed ο For this ..! ^ Ropes Tobellen