DE1198018B - Tub furnace for the production of glass or similar materials - Google Patents

Description

Tank furnace for the production of glass or similar materials The invention relates to furnace furnaces for the production of glass or similar materials. object of the invention is an improvement of such vat furnaces, which makes it possible to produce glasses of particularly good homogeneity, such as those used for the manufacture of flat glass products (Pane glass) by rolling, drawing or pressing, pouring or lifting out of the melt, especially of colored flat glass.

According to the invention, for this purpose, the furnace is transversely to its longitudinal direction in the area of the tub in which generally the refining takes place, a compartment is provided through a sole that is lower than the soles the areas of the tub located upstream and downstream of this compartment and is delimited by vertical partitions that freely connect with the upstream and downstream areas of the trough only in an upper one Allow layer of glass bath. This compartment is in its lower part with electrodes equipped for the introduction of electric current into the glass bath, which is in the glass bath through the sole or through the vertical walls of the compartment in the areas lying deeper than the sole of the adjacent parts of the tub can extend through.

The arrangement of this compartment in the tub creates an energetic Stirring the glass and consequently the desired homogenization of the glass bath. Because of this effect of the compartment provided according to the invention and for the sake of simplicity In the following detailed description, this compartment is hereinafter referred to as the "homogenization compartment" are designated.

The intensity of the convection currents within the in Forming the glass bath located in this homogenization compartment is achieved by supplying heat in the lower part of the glass bath, the greater depth of this compartment and by cooling of that area of the side walls of the same which is below the level of the The sole of the neighboring parts is increased. That through the supply of electrical Energy in the lower part of the heated glass bath rises towards the surface of the bath in a stream on which, after going over in all directions has distributed the surface of the bath, down the side walls again flows.

The speed of these convection currents depends on various Factors, in particular on the one hand the supply of electrical energy and on the other the cooling of the side walls of the compartment. This cooling is carried out according to the invention provided lowering of the sole of the homogenization compartment compared to the actual oven sole facilitated. The lowering of the bottom of the homogenization compartment can e.g. B. 20 to 80% of the height of the glass bath in the neighboring compartments. That Measure of this decrease, which determines two of the factors of which the speed depends on the convection currents, namely the depth of the bath and the cooling of the Sidewalls, will depend on the type and color of the melted glasses and the desired Chosen homogenization effect. If it is not permeable to radiation colored glasses must be the depth of the upstream and downstream Zones of the tub necessarily small and it can be proportional to the depth of the Homogenization compartment be large. On the other hand, in the case of colorless glasses Ratio of the enlargement of the depth of the homogenizing compartment to that of the neighboring compartments be smaller. The cooling of the side walls can be natural By way of the outside air, but also by any other suitable means, such as through Aeration, spraying of water in fine distribution, a water cycle, etc., take place.

The dimensions of the homogenization compartment, in the longitudinal direction of the furnace can be considerably smaller than the length of the melting compartment, at the beginning of which the batch to be vitrified is abandoned. In certain cases it may be sufficient if the length of the homogenization compartment according to the invention is about half or even less than that of the melting compartment. Under Under certain circumstances it can be up to z. B. 1 / e of the length of the melting zone can be reduced.

According to a further feature of the invention, it is possible to reduce the convection currents, which develop in the homogenization compartment to be accelerated even further by that cooled stones are provided in this compartment. These stones are in that Space arranged between the electrodes and the side walls of the compartment and so the distance between the areas of molten glass which pass through the electrodes are heated, and the cooled wall zones are shortened. These stones serve at the same time to different speeds of the downward flowing Induce convection currents that run along the cooled stones faster and along the walls are smaller. This results within this downward flowing Glass flows a shift of the individual layers against each other, through which homogenization is favored. The cooled stones can .evenly over the length of the transverse side walls and / or the longitudinal walls of the compartment be distributed. In this case the electrodes can be placed in the transverse direction of the furnace align with each other between the rows of chilled stones. In particular, can a series of vertical electrodes that enter through the sole of the compartment and which are aligned with one another in the transverse direction of the furnace, offset in a diamond-like manner be arranged opposite two rows of chilled stones. But it is also possible the electrodes and the cooling stones are asymmetrical compared to one directed transversely to the furnace To arrange vertical plane and thereby not only flow movements of the currents in vertical Planes, but also to cause rotating movements of the same in horizontal planes.

Preferably the chilled stones are passed through the bottom of the homogenizing compartment introduced through. Their height as well as their cross-section are depending on the size and Speed of the convection currents that are to be generated, selected.

The oven walls are also created at the same time by the cooled stones 'Protected against erosion.

The invention makes it possible, as can be seen, in one zone of the furnace of relatively small dimensions in the longitudinal direction of the tub, but without practically on the thermal conditions that exist in the other parts of the furnace prevail, to act, to bring about an intensive mixing of the glass ribbon, by merely increasing the depth of the tub in this zone. The invention even gives the option of the depth of the upstream and downstream of this Zone lying areas of the tub to reduce heat loss from the glass and to reduce its flow velocity in these zones.

According to the invention are also in the event that the cooling Transverse walls of the homogenization compartment in neighboring compartments disturbances, such as local Can cause reversals in the longitudinal convection currents, in the vicinity of these compartments means are provided which, with the aim of the Compensation of this cooling effect of the furnace walls on the movements within the melted glass bath. For this purpose, in the melting compartment in the immediate vicinity of the upstream wall of the homogenization compartment Electrodes or heating tubes can be provided. In the one following the homogenization compartment Compartment which generally has a hot zone within which the refining process can be terminated by the disappearance of the last gas inclusions in the neighborhood electrodes are arranged on the downstream wall of the homogenization compartment, through which an additional heating effect is brought about along these walls and which prevent the glass from coming out of the homogenizing compartment get into this following compartment, flows downwards along these walls.

Of course, these devices, heating tubes, electrodes or the like, not only to compensate for the cooling effect of the walls, but if necessary also to accelerate the natural convection movement, in other words: to regulate the speed of the convection currents in these zones to the optimal value. You can also use same goal near the upstream or downstream wall of the homogenization compartment Stirrer or the like. Be provided.

The transverse partitions extend up to a distance from the surface of the glass bath, which is between only a few and 30 '% of the depth of the Compartment is, which in the usual case corresponds to 5 to 40 cm. This training is therefore an advantage because that which gets into the homogenization compartment is out The glass coming to the melting zone comes from the hottest surface layer and that Homogenization compartment in the downstream direction after the refining zone hot Glass from the uppermost area of the glass bath in this compartment, which accordingly Remains on the surface and from which easily any remaining glass bubbles can emerge. Furthermore, through this glass the directly in the near-surface Area of flowing, downstream convection current, which the further processing equipment supplied, fed.

Some embodiments are given below as examples only of the furnace improved according to the invention, but on which the invention is by no means limited, described on the basis of the merely schematic drawing.

F i g. 1 is a plan view of a homogenization compartment according to FIG of the invention having a furnace, which is gas-heated according to the embodiment is; F i g. FIG. 2 is an axial vertical section of the FIG. 1 bath furnace shown; F i g. 3 shows a top view of a tank furnace designed analogously to the one in accordance with FIG. in its homogenization compartment cooled deflector stones provided are; F i g. 4 is a vertical section through the furnace according to FIG. 3; F i g. 5 is a plan view of a with cooling stones and electrodes in mutually asymmetrical Arrangement of equipped homogenization compartment; F i g. 6 is a vertical section according to line VI-VI of FIG. 5 and FIG. 7 is a vertical section through a homogenization compartment with electrodes arranged upstream and downstream thereof.

In the figures there is a tank furnace with a charging and melting zone 1, refining zone 2 and work zone 3, from which one or more apparatus for Processing of the molten glass supplied is referred to. With 4 they are Mouths of the burner indicated, the flames of which melt the abandoned vitrifiable Cause substances and the heating of the glass to the appropriate temperature. That extends in the transverse direction of the tub from one longitudinal wall of the same to the other Extensive homogenization compartment 110 is in the high temperature range of the furnace immediately following the actual melting zone. It's through a deeper than the sole 6 of the tub lying sole 5 and vertical partitions? and 8, their Vertices lie below the level of the glass bath, limited. If desired can also be one or both partitions 7 and 8 in the vertical plane height-adjustable weir, especially a floating weir, which increases the amount of from the one glass flowing into the next compartment above this partition regulates, be provided.

In the described homogenization compartment are in the transverse direction of the furnace aligned vertical electrodes 9 arranged through which Current is introduced into the glass bath located in the homogenization compartment.

As can be seen, the homogenizing compartment leaving the glass originating from the near-surface layer within this compartment, which has been subjected to vigorous stirring in this compartment, into that zone of the refining compartment 2, on which the flames of the burners act and which consequently is at an elevated temperature.

In the case of the FIGS. 3 and 4 illustrated embodiment of the invention has the homogenization section 110 apart from the electrodes 9 between these and the Walls of the compartment arranged cooling stones 11. This through the bottom of the homogenization compartment stones passing through can coolant flowing through them through cavities, especially air.

In this embodiment of the invention, the cooling stones 11 are diamond-shaped symmetrical with respect to each other in the transverse direction of the furnace aligned electrodes 9 arranged offset.

In the case of the FIGS. 5 and 6 illustrated embodiment are in contrast the electrodes 9 and the cooling stones 11 asymmetrical to each other with respect to a Arranged perpendicular to the furnace running vertical plane.

The electrodes 9 1,2,3 and 9'1,2,3 are fed by three-phase current. The electrodes 93 and 9'3 are connected to the same phase. F i g. 7 shows, as an example, an arrangement in which upstream of the homogenization compartment near its transverse wall? Electrodes 12 or heating tubes are provided, which counteract the cooling effect of the wall 7 on the convection currents. This figure also shows electrodes designated 13 , which are arranged downstream of the wall 8 of the homogenization compartment in the vicinity of the same and cause an additional heat supply which counteracts the downward flow of the glass emerging from the homogenization compartment along this wall.

Claims (9)

Claims: 1. Tub furnace for the production of glass or the like mineral substances, indicated by a in the area of the tub, in which the refining process of the glass normally takes place, arranged, Homogenization compartment (10) directed transversely to the tub, which by a in one deeper than the level of the furnace floors in the upstream and downstream Area of the tub lying sole (5) and limited by vertical partitions (7, 8) which is the free connection only in the area of the top layer of the glass bath with the neighboring areas of the tub and electrodes in its lower area (9) are arranged for introducing electricity into the glass bath. 2. Tub furnace according to claim 1, characterized in that the electrodes (9) are inserted through the sole of the homogenization compartment (10) into this. 3. Tub furnace according to claim 1, characterized in that the electrodes (9) are introduced into the homogenization compartment (10) through the regions of the vertical walls lying below the level of the soles (6) of the adjacent compartments of the tub. 4. Tub furnace according to one of claims 1 to 3, characterized in that cooling stones (11) are arranged in the homogenization compartment (10) in the space between the electrodes (9) and the side walls of the compartment. 5. Tub furnace according to claim 4, characterized in that the cooling stones (11) extend through the sole (5) of the homogenization compartment (10). 6. Tub furnace according to claim 4 or 5, characterized in that the cooling stones (11) are distributed uniformly over the entire length of the lateral transverse and / or longitudinal walls of the homogenization compartment (10) . 7. Tub furnace according to one of claims 4 to 6, characterized characterized in that the electrodes (9) are interconnected in the transverse direction of the furnace aligned and diamond-shaped with respect to two rows of along the transverse walls of the Cooling stones (11) arranged opposite to the homogenization compartment are arranged offset are. B. Tub furnace according to one of Claims 4 to 6, characterized in that the electrodes (9) and the cooling stones (11) are arranged asymmetrically with respect to a vertical plane running transversely to the furnace. 9. Tank furnace according to one of claims 1 to 8, characterized in that upstream and / or downstream of the homogenization compartment (1ƒ) in the vicinity of the walls of the same on the convection currents of the glass with the aim of balancing the cooling effect of the walls devices (12), such as electrodes, heating pipes or the like, and optionally electrodes, stirrers or the like in the compartment following the homogenization compartment (10) downstream near the wall of the homogenization compartment.