Glass manufacturing – Processes – Self-supporting particle making
Reexamination Certificate
2000-08-10
2002-03-26
Fiorilla, Christopher A. (Department: 1731)
Glass manufacturing
Processes
Self-supporting particle making
C065S021400, C065S030100, C065S032100, C065S120000
Reexamination Certificate
active
06360563
ABSTRACT:
FIELD OF THE INVENTION
The invention concerns a process for the manufacture of dense amorphous quartz glass granulate by producing a porous granulate from SiO
2
powder and vitrifying the granulate.
BACKGROUND OF THE INVENTION
Amorphous SiO
2
powder is obtainable for example by flame hydrolysis or oxidation of silicic compounds, by hydrolysis of organic silica compounds by the so-called sol-gel process or by hydrolysis of inorganic silica compounds in a liquid. For example, amorphous SiO
2
powder having a high specific surface area ranging from 40 m
2
/g to about 400 m
2
/g is obtained in large quantities as a byproduct during the production of synthetic quartz glass for optical wave guides. However, re-use of the powder by melting is problematic. Due to their low apparent density the powders cannot be melted directly into transparent low-bubble quartz glass bodies. Wet granulation processes are for example commonly used to increase the density of the powder, whereby an agglomeration in form of porous granulate is produced from aqueous colloidal dispersion of such SiO
2
powders by constant mixing or agitation while moisture is gradually being removed.
In a first process of this kind according to DE A1 44 24 044 it is proposed to treat an aqueous suspension of pyrogenuously produced silicic acid powder in a mixing container with rotating agitators whose rotational velocity during a first mixing phase is set at between 15 and 30 m/s and in a second mixing phase at 30 m/s or more. A coarse granulate mass is obtained after the first mixing phase. The degree of density of the said mass is increased by addition of silicic acid powder and in a second mixing phase the coarse mass is reduced by intensive mixing and beating. Water emerges on the surface of the granular mass, and gluing of the granulate is prevented by addition of more silicic acid powder. The porous and pourable SiO
2
obtained in this fashion is then dried and sintered at 1000° C. to 1200° C. for solidification.
U.S. Pat. No. 5,604,163 describes a process for the manufacture of powder from synthetic quartz glass of the kind described initially. A gel produced according to the sol-gel method from tetramethoxysilane and water is rapidly dried in vacuum whereupon it breaks up while forming SiO
2
granulate. The granulate having a particle size ranging between 100 &mgr;m and 500 &mgr;m is then placed in a sintering container of quartz glass and heated up in batches in an electric furnace at a rate of 200° C./hr to a temperature of 1150° C. and kept at that temperature for 35 hours. The quartz glass granulate obtained in this manner can be then used for quartz glass products by conventional methods such as the Verneuil method.
A pore-free quartz glass granulate is preferable in order to avoid bubble formation during melting. However, the quartz glass granulate obtained according to the known process may contain gas residues which result in bubble formation. Reduction of residual gases by longer sintering or higher sintering temperatures leads to increased time requirements and higher cost. In addition, higher sintering temperatures also encounter limits because granulate particles soften at higher temperatures and agglomerate into an undefined porous quartz glass mass.
Especially at high temperatures the quartz glass granulate may be contaminated by the material of the sintering container. Even though the risk of contamination can be reduced by the use of suitable containers, made for example of highly pure quartz glass, such containers are costly. In addition, sintering containers of quartz glass are not suitable for temperatures above about 1400° C.
SUMMARY OF THE INVENTION
The object of the invention is therefore to provide an economical process for the manufacture of dense, highly pure quartz glass granulates.
The object is achieved on the basis of the process described initially in that the porous granulate is finely dispersed in a fuel gas flame and is vitrified in the fuel gas flame.
The term ‘granulate’ is understood to mean opaque pore-covered SiO
2
granules which are composed of a plurality of primary particles; by contrast, vitrified granulates are transparent pore-free SiO
2
granules having an amorphous structure.
In the process according to the invention the porous SiO
2
granulate is exposed to a fuel gas flame and is finely dispersed, heated and vitrified therein. The fuel gas flame is more flexible as concerns temperature than in the known process, and especially the fuel gas flame permits higher temperatures. The granulate can be exposed to very high sintering temperatures in the fuel gas flame without sintering into agglomerates. At the same time any problems linked to sintering containers such as furnaces or melting pots, are avoided. In addition, contamination of the SiO
2
granulate by contact with the walls of sintering or vitrification containers is avoided.
During the passage through the fuel gas flame the pores of the granulate collapse, resulting in an amorphous and dense quartz glass granulate. High temperatures accelerate the out-diffusion of gas remnants from the porous granulate and facilitate achievement of as high a density of the quartz glass granulate as possible, reducing the required sintering time from hours to seconds.
The fuel gas flame is generated by combustion of hydrogen containing components such as hydrogen itself, or carbon hydrogen compounds such as propane or acetylene. Reaction partners may be oxygen, oxygen compounds, halogens and halogen compounds.
It is of substance that the granulate particles do not agglomerate during the vitrification. Agglomeration is prevented in that the granulate is dispersed in the flame in fine distribution and is exposed to the flame in such fine distribution. For example, the granulate may be blown into the flame, sprayed or poured in. The individual granulate particles are heated in the fuel gas flame to high temperatures within a short time period while separate from one another due to the fine dispersion so that they cannot become glued together. The fine distribution assures that all the particles are exposed to the flame evenly and, furthermore, at a particularly high temperature, and are compacted.
The process according to the invention allows a continuous manufacture of SiO
2
granules in that the granulate is being continuously fed into the fuel gas flame.
Particularly simple is a procedure whereby the granulate is poured into the fuel gas flame. Here the granulate is poured from above in a finely distributed form into the fuel gas flame. The direction of the flame is not of substance; it may be pointed vertical to the direction of the falling material, parallel to it or on a diagonal.
In an equally preferred procedure the granulate is supplied to the fuel gas flame in a gas stream. The gas stream can simultaneously assist in the local distribution of the granulate in the fuel gas flame by being used for whirling of the poured granulate so that individual granulate articles are carried along by the gas stream in the direction of the fuel gas flame. The gas stream may for example generate a whirling bed of the poured material and the material can be treated chemically and thermally at the same time. The gas stream can also serve as carrier for supplying the granulate to a burner, the latter also producing the fuel gas flame, in that the gas stream is charged with the granulate and fed into the burner.
In an alternative method thereto it has also been shown to be advantageous for the granulate to be fed into the fuel gas flame by means of a vacuum. In this method the granulate is suctioned into the fuel gas flame. The vacuum may be for example generated within the fuel gas burners by equipping it with a venturi jet into which the granulate is fed.
It has been shown to be advantageous to adjust the fuel gas flame to a temperature of at least 1600° C., but preferably in the range from 2000° C. to 2500° C. However, a precise measurement of the fuel gas flame temperature is difficult for, among others, the introduction of the SiO
2
gran
Gerhardt Rolf
Köppler Rainer
Ponto Werner
Werdecker Waltraud
Fiorilla Christopher A.
Heraeus Quarzglas GmbH & Co. KG
Tiajoloff Andrew L.
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