DE1011589B - Duese for drawing sheet glass - Google Patents

Description

Nozzle for drawing sheet glass The previously general for drawing Nozzles used for sheet glass according to the Fourcault method are made of chamotte. For such nozzles. are with regard to the inlet of the nozzles, the nozzle slot forming facet and the subsequent nozzle bar based on many years of experience Forms have been developed that allow sheet glass to be drawn flawlessly.

The nozzles made of chamotte, however, due to their chemical and physical behavior towards the glass as well as its mechanical properties Sources of error that are. Noticeable in the glass in the form of combs, threads and the like do. Furthermore, when the pubic nozzles are heated, fire cracks can be seen on the Do not avoid facets that affect the quality of the glass. Through the The mentioned phenomena also have a strong influence on the service life of the pubic nozzles.

It has also already been suggested that instead of the Schamotted nozzle To use hollow body trained nozzles made of steel. Avoid the hollow steel nozzles With the right choice of steel, the disadvantages of the pubic nozzles described above, but have the disadvantage of high heat radiation, which also occurs when filling the cavities with heat-insulating materials are not sufficiently reduced can be. With the high heat radiation of the hollow steel nozzles a premature occurs Freezing in particular on the edges of the glass ribbon, which causes the drawing process comes to a standstill unless special heating devices are arranged. For also known nozzles made of heat-resistant metal with open-topped, with insulating materials The same applies to filled U-shaped side walls.

According to the invention it is proposed that the nozzle be made of highly heat-resistant, to manufacture thin-walled, preferably 1 to 5 mm thick sheet steel, its single-walled Shaping exclusively through the inlet of the nozzle that forms the nozzle slot Facet and the subsequent nozzle spar is determined. So this will put in place the previously proposed hollow: steel nozzles created a single-walled steel nozzle. By using a single-walled steel nozzle it is achieved that the through the The hot glass mass passing through the nozzle merely heats up one steel wall releases to the stationary glass mass surrounding the nozzle, which is caused by the ongoing supply of heat while compensating for the radiation losses to the drawing chamber to about the same Temperature is maintained.

In cases where the radiation losses of the surrounding the nozzle Glass mass not full due to the constant supply of heat through the nozzle wall can be compensated, the heat radiation of the glass mass surrounding the nozzle by means of a suitable insulating cover opposite the pulling chamber in a known manner be reduced.

Due to the relatively minor :, constant heat dissipation through the single-walled sheet steel nozzle continues to charge an increase in the drawing speed achieve, whereby the extent of the heat dissipation can be kept within such limits, that premature freezing of the glass mass, especially on the shelves, without additional Effectively prevent heating medium .loads.

To avoid the deterioration of the glass quality, e.g. B. by It is discoloration or blistering as a result of oxidation of the nozzle material of course necessary, the nozzle made of highly heat-resistant and against glass, if possible to manufacture indifferent, preferably high-chromium alloy sheet steel. For the same Basically, the inner surface of the nozzle can be nitrided, preferably on the facet. Covering the facet with precious metal, e.g. B. platinum or platinum compounds, serves the same purpose, whereby the noble metal od by rolling, riveting. can be applied. Instead of nitriding or platinizing or in addition a protective gas atmosphere can also be arranged between the nozzle bars. The arrangement of such a protective gas atmosphere between the nozzle bars is charged for example through between the facet and the nozzle cap, expediently in a recess the nozzle wall arranged tubes with slots or other outlet openings Achieve, to which a protective gas is continuously supplied. At the bottom of the inlet of the nozzle are expediently essentially horizontally extending Stiffening plates attached. Furthermore, on the outside of the nozzle inlet plates stiffening ribs running horizontally and / or vertically in a manner known per se be provided.

To avoid radiation losses, the spar height of the nozzle dimensioned only as large as it is necessary to form the spring onion. For the same reason, the distance between the facet and the spar is also useful dimensioned so small that a single wall-free drawing onion is just guaranteed is.

The support of the new steel nozzle is also made of highly heat-resistant Sheet steel holding devices located at the nozzle ends. These holding devices can either be designed as a hollow body, which may reduce the tendency to lower cancel the nozzle or at least reduce it, or you can do without be designed as a grid body on these advantages.

The holding devices are attached to the steel nozzle that they when operating the nozzle to avoid radiation losses completely in the Glass mass are submerged.

The holding rods that come with the holding devices for the nozzle expediently are connected in the manner of a joint, `-earths as coolants which can be switched off flow through Double tubes formed.

The outer holding tubes are also made of highly heat-resistant material Made of steel. During the heating of the drawing chamber is used as a coolant for the Handrails used water, which at the end of the heating, it by compressed air a, is inflatable. The valves controlling the water and the compressed air are like this coupled so that compressed air is inevitably introduced when the cooling water is switched off, which at the same time displaces the water. In this way there is an evaporation of the Effectively avoided water, which can lead to steam explosions. During operation the nozzle, the compressed air can be used as a coolant for the support rods will.

The subject matter of the invention is illustrated in the drawing, for example. 1 shows an embodiment of the new steel nozzle in longitudinal section. line II-II of Fig. 2, Fig.2 the same steel nozzle in cross section along line I-I of 1, 3 show a nozzle end with a holding device designed as a hollow body in longitudinal section, FIG. 4 the embodiment according to FIG. 3 in plan view, FIG Nozzle end with a holding device designed as a lattice body in longitudinal section, FIG. 6 shows the embodiment according to FIG. 5 in plan view, FIG. 7 shows a holding rod for the holding devices according to FIGS. 3 and 4 or FIGS. 5 and 6 in longitudinal section, 8 shows half of a nozzle with an associated holding device in a diagrammatic view Depiction.

As can be seen from FIGS. 1 and 2, the single-walled consists of Highly heat-resistant, thin-walled sheet steel made from the nozzle inlet sheets 1, the shape of the inner walls of the known nozzles made of fireclay correspond-. At the upper ends of the nozzle inlet plates 1 are horizontally externally extending sheets 2 welded, which in turn at a suitable distance from the nozzle facet 3, d. H. welded at the joint between sheets 1 and 2, suitably carry sheet metal parts which run vertically upwards and which support the nozzle bar 4 form. The height of the nozzle bar 4 is only as large as it is to form the spring onion is required. This way, unnecessary radiation losses are avoided avoided.

Furthermore, in order to avoid radiation losses, the distance between facet 3 and spar 4 only so large. That still a flawless Pull onion growth is guaranteed.

At the lower ends of the inlet plates 1 are expediently horizontal running stiffening plates 5 welded on. The inlet plates 1 can continue to on the outside with welded, horizontally or vertically Stiffening ribs 6 and 7 respectively.

As the right half of Fig.2 illustrates, between facet 3 and spar 4, the horizontally extending sheet 2 with a recess 8 for receiving equipped with slots or other outlet openings, not shown Pipes be provided through which a suitable protective gas for the purpose of creating a Protective gas atmosphere is supplied between the nozzle bars 4.

The bracket of the new single-walled, made of highly heat-resistant, thin-walled Sheet steel existing nozzle takes place according to FIGS. 3 and 4 through finite the nozzle ends connected hollow body 9, which is also made of thin-walled, highly heat-resistant. Steel sheets are made. Instead of the hollow body 9 can also be connected to the nozzle ends Grid body 10 made of thin-walled, highly heat-resistant sheet steel according to the Fig. 5 and 6 are used as holding devices.

In. In both cases, the holding devices, such as FIGS. 3 to 6 can be seen so- attached to the steel nozzle that they are in operation of the nozzle completely submerged in the glass mass to avoid radiation losses are. The immersion depth of the nozzle in the glass drawer is adjusted with holding rods so that that the nozzle spar 4 is only next !. a few millimeters above the glass surface n (cf. Fig. 3 and 5) protrudes.

In both cases, the holding devices 9 and 10 are still included upwardly projecting bearing eyes 11 for the articulated attachment of the support rods Mistake. As shown in FIG. 7, the support rods consist of double tubes 12, 13, of which the outer tube 12 is also made of heat-resistant steel is.

The upper end of the inner pipe 13 is supplied with cooling water through the pipe 14, which passes through the holes 15 into the outer pipe 12 at the lower end of the inner pipe 13 and leaves the outer pipe at the upper end through the nozzle 16.

After the end of the heating time of the drawing chamber, the cooling water supply is turned off through the valve 17. At the same time, the valve 18 in the line 19 is opened and compressed air is introduced through the line 19, which displaces the water within the pipes 12 and 13. Even while the nozzle is in operation, the compressed air can continue to be used as a coolant for the holding rods. Fig. 8 still illustrates the half nozzle with the, holding device arranged at one end in graphical representation.

Claims (7)

PATENT CLAIMS: 1. Steel nozzle for drawing sheet glass, in particular for the Fourcault process, characterized in that it is made of highly heat-resistant, consists of thin-walled sheet steel, whose single-walled shape is exclusively due to the inlet of the nozzle, the facet (3) forming the nozzle slot and the subsequent one Nozzle bar (4) is determined. 2. Nozzle according to claim 1, characterized in that the inner surface of the nozzle is nitrided, preferably on the facet. 3. Nozzle according to claim 1, characterized in that the nozzle inner surface, preferably on the facet, with precious metal, e.g. B. platinum or platinum compounds is covered. 4. Nozzle after A dLr claims 1 to 3, characterized by the arrangement of a protective gas atmosphere between the nozzle bars. 5. Nozzle according to claims 1 to 4, characterized in that that at the lower edge of the inlet plates (1) extending essentially horizontally Stiffening plates (5) are attached. 6. Nozzle according to claims 1 to 5, characterized characterized in that the inlet plates (1) on the outside with attached stiffening ribs (6, 7) are provided. 7. Nozzle according to claims 1 to 6, characterized in that the spar height is only dimensioned as large as is necessary to form the draw onion. B. nozzle after the. Claims 1 to 7, characterized in that the distance between the fa, -cette (3) and the spar (4) is only dimensioned so large that a perfect drawing onion is still guaranteed. 9. Nozzle after. Claims 1 to 8, characterized in that holding devices also made of highly heat-resistant sheet steel are attached to the nozzle ends. 10. Nozzle according to claim 9, characterized in that the holding devices are designed as hollow bodies (9). 11. Nozzle according to claim 9, characterized in that holding devices are designed as a grid body (10). 12. Nozzle according to claims 9 to 11, characterized in that the holding devices are attached to the nozzle that they are completely submerged in the glass mass when the nozzle is operated. 13. Nozzle according to claims 9 to 12, characterized in that the holding rods connected to the holding devices are designed as double tubes through which cool media which can be switched off flow. 14. Nozzle according to claim 13, characterized in that the holding rods are provided with supply lines for water and compressed air. 15. Nozzle according to claim 14, characterized in that the valves controlling the water and the compressed air are coupled so that compressed air is inevitably introduced during operation when the cooling water is turned off after the drawing chamber has been heated for cooling, which simultaneously displaces the water. 16. Nozzle according to claims 13 to 15, characterized in that the holding tubes are articulated with the holding devices of the nozzle. 17. Nozzle according to claims 13 to 16, characterized in that the outer holding tubes are made of highly heat-resistant steel. 18. A drawing chamber equipped with a nozzle according to claims 1 to 17, characterized in that a heat-insulating cover is arranged above the glass mass located outside the nozzle. Contemplated publications: USA. Patent No. 1,872 699th.