DD265890A1 - ELECTRICALLY HEATED PURIFICATION OF A MELTING FUEL FOR SILICATIVE SUBSTANCES - Google Patents

Abstract

The invention relates to an electrically heated passage of a melting furnace for siliceous substances, in particular low-alkali glass, with a passage tube made of heat and corrosion-resistant metal. According to the invention, one or more stabfoermige resistance heating elements, for. B. tungsten, parallel to the Laengsachse within the passage tube at a distance to the passage tube wall in preferably a plane. They are mounted outside of the inlet pipe, known per se Stromzufuehrungen. The effective length of the resistance heating elements is 0.3 to 1 times the passage tube length. The heating of glasses of low conductivity, even during start-ups and temperature-induced flows, takes place without electrical feed-through in the inlet pipe. Fig. 1

Description

For this 2 pages drawings

Field of application of the invention

The invention relates to an electrically heated passage of a melting furnace for siliceous substances, especially low-alkali glass, with a passage tube made of heat and corrosion-resistant metal.

Characteristic of the known state of the art

Between melting furnace for silicate materials and laboratories, homogenizing equipment, food and derj, wich arranged passages for the melt are heated for various reasons. This may be necessary during start-up, to set or maintain a certain temperature level, to improve the homogeneity or quality of the Schmölze, etc.

Already from DE-PS 1018593 the use of electric energy is known for this purpose by recessed in the passage of a fuel-fired furnace or arranged in the recessed passage electrodes, between which the melt assumes a higher temperature by Joule heat.

Such Behnizung requires adequate conductivity of the melt, is unsuitable for start-up operations and increases the wear of the already heavily loaded passage.

For highly corrosive melts and particular smelting, tubular passages of heat and corrosion resistant metals, e.g. made of precious metals, come into use.

It is known from DE-AS 1069345 to surround such a passage tube with a heating coil which is connected to a regular voltage source.

-2- 265

In addition to the complicated execution of such heating, mi *. Breakage of the heating coil, this solution has the disadvantage, c * iß the heat transfer to the melt is very slow and with losses.

In the known from US-PS 4352687 passage of molybdenum, tungsten, tantalum, steel or precious metals only consisting of the same material connecting piece of passage pipe is externally heated to the connected conditioning channel. The installed heater is here almost exclusively used to start the unit, which is used with this design principle a long time to melt the passage.

An adjustable heatable passage pipe is known from DE-AS 1056794. The heating voltage is connected to dib ends of a platinum tube, which connects the melting furnace and the homogenization container and is surrounded by a ceramic jacket.

Heating the entire passage tube in many cases does not meet the technological requirements; it has thermal disadvantages caused by the heating of the melt in the interior of the passage tube and often lead to desson thermal overload. Finally, the application of precious metals leads to unreasonably high costs and must be high-quality, z. As optical, glasses remain limited.

An effective heating of the passage, especially in the start-up phase of the oven, is known from US-PS 4029887. The preferably made of molybdenum passage tube extends from the furnace center to a connecting channel. The heating voltage is applied between a passage opposite electrode near the furnace bottom and an electrode near the passage tube end in the passage. The flow of current is successively through the melt and the passage tube and it is so strongly influenced by the temperature-dependent electrical conductivity of the melt. This leads to failure of certain temperatures to the failure of such arrangements.

For a number of low-alkali and thus electrically poorly conductive glasses such solutions are not applicable.

In certain operating conditions, there is a risk of freezing of the passage, which is an impairment of the reliability of the melter.

Finally, it is known from DD-WP 227426 to arrange a resistance heating element, for example, in the passage of glass melting furnace within the melt. The Z. B. consisting of tungsten resistance heating elements has the shape of a hollow cylinder, is provided with meandering or helical conductor tracks and its longitudinal axis is oriented in the flow direction of the melt.

Such a resistance heating element is technically difficult to implement and brings problems with respect to the permanent fixation of the conductor tracks with it. In addition, the assembly of one, possibly also a plurality of successively arranged or parallel resistance heating elements in the passage penetrations in the passage walls, which cause significant metallic insulation tubes and insulation problems sealing.

Due to the susceptibility of Widerstandsheizelement and bushings, the reliability of such a passage is adversely affected.

Object of the invention

It is the object of the invention, by reducing the susceptibility to increase the reliability and life for electrically heated passages with metallic passage tube and to reduce the manufacturing cost.

Explanation of the essence of the invention

The invention has for its object to make a resistance heating of the melt in the metallic passage tube of a preferably suitable for low-alkali glasses passage in which the Durchlaßrohrtemperatur does not exceed the melt temperature, heating elements of simplified construction have high mechanical stability and electrical feedthroughs are avoided in the passage tube.

The object is achieved erfindungstamäß characterized in that one or more rod-shaped resistance heating elements of a heat and corrosion resistant, electrically conductive material, eg. B. tungsten, are arranged parallel to the longitudinal axis within the passage tube at a distance to the passage tube wall in preferably a plane. The Widerstandsheizeiern jnta be supported by outside the passage tube mounted, known power supplies; with these the Widerstandshelzelemnnte be electrically connected. The effective length tines, or at several, each st.abförmigen Wideretandsheizelemontes is 0.3 to 1 times the Durchlaßrohrlänge.

According to further features of the invention, the cross-sectional area of the rod-shaped resistance heating elements and their support in Strömunosrichtung in the passage tube 8% to 12% of the cross-sectional area of the passage tube. The resistance heating mantles have a diameter of 5mm to 15mm, preferably 10mm. They are connected in series in series and / or parallel connection.

Furthermore, there is a passage tube advantageously preferably made of tungsten, is formed by plasma spraying and subjected to a subsequent Vakuumglüh ^r · and Vakuumsinte treatment. On the outer circumference, a protective layer is applied or the tube is surrounded by it, which consists of glass powder and / or powdery ceramic materials with additives reducing ingredients.

According to other features, the one or more resistance heating elements, on the holder opposite end, electrically conductively connected to the passage tube. Then, the electrical resistance of the passage tube between the connection point and the power supply point at the passage tube at most one third of the total electrical resistance of the or the Widerstandshei <elements. In a variant, the or the resistance heating elements is electrically isolated against the inner wall of the passage tube from. Finally, one feature relates to the introduction of resistance heating mantels into the lock-up tube, which takes place from one or both sides.

Such a passage donated, due to its structural and energy advantages, to reduce the flow cross-section compared to known passages. Even aikaliarme glasses of low conductivity can in the passage

be heated sufficiently. Starting operations and disturbances in the temperature drum of the melting furnace are reliably controlled with regard to the passage, which increases the reliability of operation.

Resistant heating elements of the simplest geometrical form and safe ( soundproofing and supercooling) reduce the system costs and increase the service life of the system

Passage through the pipe lower Durchlaßrohrtemperatur just as favorably influenced. Ausfuhrt! ngsbtisplel

The invention will be explained with reference to schematic references of the passage, for example.

Fig. 1: a vertical longitudinal section of the passage with electrically connected to the passage tube

Wider8tar.d8heizelemc> nt; Pig.2: a horizontal longitudinal section with insulated Widerstandshelzolementen in series.

The passage directs the molten glass from a melting furnace 1 in a forehearth 2 through the furnace walls 3; he is near that Furnace bottom 4 is arranged. The passage tube 5 has-depending on the throughput-a diameter of 60mm to 300mm, at

a wall thickness of 3 mm to 10 mm, and is preferably made of tungsten. Other heat and corrosion resistant

Materials are equally suitable, with molybdenum being one of them. The manufacturing process - plasma spraying, Vacuum annealing for the removal of hydrogen from the structure and a sintering treatment in a vacuum or a suitable one Atmospähre-characterize the passage tube 6 and give him favorable Einsatzzeigenschafton at high temperatures in

corrosive melts.

The passage tube 5 is surrounded by a protective layer 6 for protection against oxidation. This is a tight pack

between the passage tube 5 and the surrounding walls cder is applied to the passage tube 6 as a gas-impermeable layer by known methods. It consists of a mixture of glass powder, SiO ₂ , ZrO ₂ , Al ₂ O ₂ and optionally

Admixtures of reducing components or one of these components. By partial crystallization on heating

This powdery mixture solidifies under slightly reducing Bedingu igen to a firmly adhering layer with vitreous

Proportion of. Lasting ensures the necessary gas impermeability. It is advantageous to such reducing admixtures too

which do not form gaseous products when oxidized. Molybdenum or tungsten powder meets this requirement to an adequate degree.

Parallel to the ling axis of the passage tube 5 is shown in FIG. 1 in this in the lower half between the central axis and the tube wall

a resistance heating element 7 is arranged. Its effective length is about 80% of the Durchlaßrohrlänge - it will be

Ratios from 0.3 to Ifachen are selected - and it depends on the required heat output and the rod length Diameter of 6 mm to 15 mm, preferably 10 mm used. Me the Widerstanrlsheizelement 7 consists of Tungsten or similar electrically conductive, heat and corrosion resistant material. At one end that will Resistance heating element 7 of a connecting piece & was added, which outside of Üurchlaßrohres δ with a Power supply 9 is mechanically connected. The power supply 9 is performed by known construction elements

led the furnace bottom 4. Resistance heating elements 7 and current control 9 are electrically connected.

The other end of the resistance heating element 7 is mechanically fixed by the connector 10 and electrically conductive with the Through tube & connected. The same applies to that in the vicinity of the mounting location of the connector 10 attached Anschiußstück 11, which in turn is connected to a power supply 9 '. The Wide; stand of the part of the passage tube. 5

between connector 10 and connector 11 may be at most one third of the resistance of the resistance heating element 7. A significant heating of the passage tube S through the Stromduichgang is largely avoided.

The connector 11 and the power supply 9 'are embedded in the protective layer β. The power supply lines 9; 9 'are connected to a controllable current source 12. The cross-sectional area of the passage tube B is within the cross-sectional area of the c-type heater assembly Durchlaßrohres 5 in the flow direction - in Fig. 1, the connector 10 and optionally the beyond projecting part of the Connecting piece 8-in a predetermined ratio, to an unfavorable influence on the flow conditions in

and to report after the passage. Thus, this cross-sectional area is not more than 8% to 12%.

In the passage shown in Fig. 2 paths, ι the required electrical power two hinerei.iandergeschaltet come Resistance fusible elements 7 for use. In other variants we'den parallel resistance resistors 7 or

a combined interconnection applied. So is also an advantageous adaptation to existing

Electricity supply systems can be realized. The Wldertfandsheizelemente 7 would possibly in several levels

one above the other> arranges; however, one-level adoption is preferred.

Di? .'uomiufOh .. r.jen 9 are passed through the furnace walls 3 of the 2 Vooierdes. Width of forebear 2 or height of Passage above the furnace bottom 4 determine the type of attachment of the power supply lines 9; also the attachment of

above through the Ofer.raum and the melt is applicable.

Within the passage tube 5, the ends of the W Jersta.idshelzelemente 7 are connected by the contact bridge 13. The support 14 holds the contact bridge 13 at a distance / ur Durchlaßrohrwand and thus the Widerstandsheizelpmente 7 parallel

to the longitudinal axis. It also consists of a 'stranded and corrosive' material and does not require a mechanically strong connection with the passage tube 5.

The gleichiangen resistance fusible elements 7 each have about half the length of the passage tube 6, so that the effective Length of 0.5 times the Durchlaßrohrlän e amounts. The total resistance of the heating arrangement is determined by the series connection of the resistance heating elements 7.

For long passages, it proves to be advantageous to insert the resistive arm elements 7 of both rare in the passage tube 6. This know both > .i of the variant with support 14 and with electrical connection of the resistance heating elements 7 to the passage tube 5 happened. The resistance heating elements 7 are then preferably guided to the middle of the passage tube 5 and thus the passage holholt on the entire length. The heating groups are preferably from separate power sources 12g: iepeist.

Claims (9)

1. Electrically heated passage of a melting furnace for siliceous substances, especially low-alkali glass, with a passage tube made of heat and corrosion-resistant metal, characterized in that one or more rod-shaped resistance heating elements (7) made of a heat and corrosion resistant, electrically conductive material, eg. B. tungsten, parallel to the longitudinal axis within the passage tube (5) are arranged at a distance from the Durchlaßrohrwand in preferably a plane from outside the passage tube (5) mounted, known per se power supply (9, 9 ') are supported and electrically are conductively connected and that the effective length of each or each rod-shaped resistance heating element (7) is 0.3 to 1 times the Durchlaßrohrlänge. Z. passage according to claim 1, characterized in that the cross-sectional area of the rod-shaped resistance heating elements (7) and their holding ments in the flow direction in the passage tube 8% to 12% of the cross-sectional area of the passage tube (5). 3. passage according to claim 1 and 2, characterized in that the rod-shaped resistance heating elements (7) have a diameter of 5 mm to 15 mm, preferably of 10 mm. 4. passage according to claim 1 to 3, characterized in that the rod-shaped resistance heating elements (7) are connected in series and / or parallel connection with each other. 5. passage according to claim 1 to 4, characterized in that the passage tube (5) is preferably made of tungsten, is formed by plasma spraying with subsequent Vakuumglüh- and sintering treatment and that a protective layer (6) except applied to the passage tube or the tube surrounded by glassmeh! and / or powdery ceramic compositions is composed with additives of reducing components. 6. passage according to claim 1 to 5, characterized in that the / the rod-shaped resistance heating element (s) (7) on the holder opposite end to the passage tube (5) is electrically connected / and that the electrical resistance of the passage tube (5 ) between said connection point and the power supply point at the passage tube (5) is at most one third of the total electrical resistance of the / the resistance heating elements (s) (7). 7. passage according to claim 1 to 5, characterized in that the / the rod-shaped resistance heating element (s) (7) on the holder opposite end against the inner wall of the passage tube (G) are supported. 8. passage according to claim 1 to 5 and one of claims 6 or 7, characterized in that the resistance heating elements (7) of a. Side are inserted into the passage tube (5). 9. passage according to claim 1 to 5 and one of claims 6 or 7, characterized in that the resistance heating elements (7) are introduced from both sides into the passage tube (5).