NL8100433A - Pouring hole for a non-metallic melting furnace. - Google Patents

Description

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Title: Pouring opening for a non-metal melting furnace.

The invention relates to a pouring opening for a melting furnace for non-metallic materials, in particular inorganic oxides intended for the manufacture of mineral or ceramic fibers, refractory products or non-metallic granules.

The quality of these products depends to a large extent on the chemical and thermal homogeneity of the liquid bath in the casting device, as well as on the regularity and the shape in which a jet leaving the oven, for example a wire roller, a granulating drum or a mold touches.

Any variation in the above-mentioned conditions negatively affects the quality and / or the quantity of the end product, either that the physical or chemical properties decrease or that the efficiency of the device decreases, such as for instance a wire roller or a granulator.

15 In known non-metal melters, these include cupola furnaces ($ 5%) and furnaces with immersed or non-immersed electrodes (5%), the pouring apertures are formed by a system of water or water jacket cooled tubes, optionally lined with refractory material, but normally due to the molten material itself, subject to clogging due to a layer on the cooling surface making the delivery irregular. This is due to a lack of control associated with this shape of the pouring openings. It follows that changes in viscosity in the material to be cast, variations due to the thermal and / or chemical irregularities of the liquid bath, are reflected in the release resulting in the formation of screen-like jets, crusts or icicles that delay delivery and require frequent cleaning.

The obstacles or malfunctions adversely affect the quality and quantity of the end product.

The pouring opening also has to be pierced often, which is done with very primitive means "eg metal bars with all the risks and disadvantages thereof.

The manner in which a pouring opening is constructed therefore constitutes a very sensitive point of the non-metal casting installation with a view to the manufacture of mineral or ceramic fibers or refractory products or non-metal granules.

The object of the invention is to provide means for a pouring opening which make it possible to control the thermal conditions so that the disadvantages described above can be obviated.

This object is achieved at a pouring opening, which consists of a block that is set in the wall of the oven, in that it contains a central passage of graphite or carbon with a widening on the inside of the oven, which passage is located in a refractory 10 with a certain electrical resistance and which contains at least a metal or graphite electrode, which at least partially envelops the central passage.

The idea which forms the basis for the invention is to be seen in proposing means which, due to the special construction, are particularly suitable for controlling the release, whereby the thermal conditions of the pouring opening are also controllable, which regulation is based on the principle of electric heating.

For example, the choice of graphite as the material for the central passage is very advantageous, since graphite is not attacked by most inorganic oxides.

According to a first embodiment of the invention, one of the electrodes, which consists of refractory steel or a stainless superalleaction which is resistant to high temperatures, is in the refractory mass surrounding the central passage of graphite and itself the second electrode forms. The metal electrode can be in the form of a plate or a cylindrical, respectively. conical grid. When an electric current flows through the two electrodes, a homogeneous heating occurs due to the Jcule effect of the refractory mass, which forms an electrical resistance. The resistance value of the refractory material 30 is chosen accordingly. This high temperature refractory mass transfers the heat by conduction to the central graphite passage, the temperature of which can be changed by controlling the power supply to the system. The electrical supply can consist of an alternating current or a direct current.

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According to a second embodiment, "the round outer electrode consists of graphite and is integral with the central passage.

The thickness of the electrode surrounding the central passage is chosen such that strong heating occurs as a result of the current passage. The heat propagates on the one hand by conduction in the graphite at the furnace side of the central passage and on the other hand by refractory concrete which has a good heat conductivity, but the flow is difficult to conduct, to the cylindrical part of the central passage. The refractory concrete is based on aluminum or chrome magnesium.

In order to prevent heat losses towards the central passage, it is useful to shield the outer surface of the round graphite electrode by a large heat resistance which is adhered to the surface or embedded in the concrete at some distance from that surface.

In case the length of the central passage is short, the heat transfer by conduction in the graphite alone will be sufficient to obtain the intended effect of the temperature control, so that the refractory concrete between the two electrodes is unnecessary. The space thus formed may then contain air or a neutral or reducing gas, respectively.

According to a third embodiment of the device according to the invention, instead of a metal electrode in insulating refractory materials, a copper coil is embedded which is water-cooled or a high-temperature-resistant alloy, which coil encloses the central passage of graphite and the two ends of which are connected to an alternating current source of suitable frequency. The magnetic field generates induction currents in the central passage from graphite, which causes the temperature to rise and which varies as a function of the power and the frequency used, which principle is used for induction furnaces with indirect heating.

The shape of the coil and the dimensions of the windings can be adapted to the different shapes and sizes of the central passage, enabling temperature control or a certain temperature drop, respectively, along the length of the passage. Be it a heating via conductive graphite or heating 35 by induction, it is useful in both cases according to the invention to provide 8100433 - the part of the passage of graphite on the outflow side with a cooling jacket which is provided by a suitable fluid. chilled, for example water, synthetic oil, etc.

The role of such a variable flow cooling jacket is twofold, on the one hand it serves to harden the pouring opening by hardening of the material in the central passage when the electrical supply is interrupted and the greatest possible amount of fluid passes through the jacket and on the other hand for controlling the temperature in case the product flowing through the passage 10 is significantly overheated. Effective cooling lowers the temperature of the product flowing through the nozzle and regulates the viscosity, a constant value of which is important for the proper functioning of, for example, a wire drawing device or a granulator behind the oven. The good heat conductivity of graphite increases the efficiency of the cooling jacket.

According to an embodiment of the invention, said cooling jacket can consist of a ring which is screwed onto the end of the central tube and which can also serve for the power supply. According to a second embodiment, a spiral cut is made directly into the thickness of the central passage and closed and sealed by a sleeve or sleeve of graphite or metal in the form of a tube which can slide over the channels thus formed.

The formation of ssln casting current can be easily accomplished by limiting the cooling liquid with regard to the protection of the metal parts and increasing the heating current in the electrodes or the induction coil as much as possible.

The chemical and thermal homogeneity of the liquid bath in the melting furnace is of great importance for the quality of the end product.

A special feature of the invention is that a secondary homogenization of the bath takes place just before it reaches the pouring opening. This is achieved by arranging a metal sleeve around the refractory graphite, which is sealed outwardly and a gas passage to the interior of the furnace is formed along the inner wall of the sleeve and the concrete. A conduit serving to transport an indifferent or reducing gas is connected to a mixing chamber contained in the refractory mass which is sealed outward. Gas under 8100433 -5- pressure passes through an annular mixing chamber which is formed by the space between the refractory material and the inner surface of the pipe and between the furnace envelope creating a controllable mixing movement in the fluid bath at the entrance of the pouring opening. This movement causes thermal and chemical homogenization of the bath at this point.

In order to prevent the entry of melt products into said space, baffles may be present or the gas may be under constant pressure. The outer casing plate may advantageously consist of stainless steel, which is refractory.

The pouring opening according to the invention can be gastight in order to prevent the leakage of treatment gas on the one hand and to prevent the outside air from entering the furnace on the other hand. O-rings are used for a gas-tight seal.

In order to permit longitudinal expansion of the device according to the invention and furthermore to prevent bursting of the various components due to temperature increases and decreases, the attachment to a casting mold or the like takes place by bolts on which springs can be compressed or de-tensioning as a function of relative movements of the device relative to the furnace wall. Sliding connections with 0-rings guarantee the sealing in every position. The water cooling circuits cool the O-rings from overheating and limit thermal expansion of the mechanical fasteners. Transverse expansion 25 is made possible by joints whose dimensions and function are adapted to the properties of the refractory material used.

In order to limit heat losses, the outer surface of the refractory surrounding the central passage is protected by a ring; which consists of insulating material that can withstand high 30 t temperatures.

In order to prevent oxidation of the outer end of the passage from graphite, the surface thereof is bubble-protected by atmospheric attack by an annular cap of refractory material, preferably of electrically molten chromium magnesium, which forms the funnel.

A shield against the indifferent gas consisting of a ring, which surrounds the end of the central passage, provides a good protection 8100433-6 of the graphite against oxidation from the atmosphere. Further details of the invention are discussed with reference to the drawing. In the drawing: Fig. 1 shows a longitudinal section through a first embodiment of a pouring opening according to the invention; fig. 2 shows a cross section through the device; 3 and b are longitudinal sections through two other embodiments of the device according to the invention.

The pouring opening for a non-metal melting furnace consists of a graphite central passage 1 which is conically widened upstream and which consists of a ring 9 which forms a shaft downstream.

The central passage 1 is surrounded by refractory material 2.

The heating electrodes 3 can consist of metal or graphite 15 or of an induction coil which is embedded in the refractory mass 2 and which is connected by connections 6 to an electric voltage source.

A. thermal insulating layer 21 serves for good heat distribution in the central passage 1 and prevents heat losses to the furnace coating itself.

The central passage 1 and the refractory mass 2 is surrounded by an outer plate 7 · Bounded by an annular channel in the refractory mass and the plate 7 there is a mixing chamber 13 for treatment gas which serves to provide a thermal and chemical homogenization of the bath before it reaches the central passage. The gas enters the mixing chamber 13 through a supply pipe 8 and is led to the bath through a very narrow gap located between the refractory mass 2 and the plate 7 ·

The heat flow to the pouring opening 9 is controlled by a water cooling 5 in the ring 1 which surrounds the central passage 1 of graphite 30 and serves to receive the pouring funnel 9. The ring 20 which resists the indifferent gas provides additional protection against oxidation of the graphite.

The outer surface of the refractory mass 2 is protected by an insulating plate 10.

35 The whole can be attached to a casting mold of the melting furnace by means of fixings or springs 12 with a seal by means of O-rings 15 · 8100433 -7-

Water cooling circuits 11 are located near said fasteners.

As can be seen from Figs. 1 and 2, the passage consists of two concentric parts 1 and 11 which form the actual pouring channel 1 and can be taken apart.

8100433

Claims (13)

1. Casting opening for a non-metallic melting furnace, in particular inorganic oxides for the manufacture of mineral or ceramic fibers, refractory products or non-metallic granules, consisting of a block to be placed in the wall of the furnace, characterized in that it includes a central passage of graphite or carbon with a widening on the inside of the furnace, which passage is contained in a refractory mass of a certain electrical resistance and which contains at least one metal or graphite electrode the central passage at least partially encloses. Device according to claim 1, characterized in that one of the electrodes is annular and consists of refractory steel, a stainless superalleage or of graphite and prayer is in the refractory mass surrounding the central passage of graphite which itself forms the second electrode. . 3. Device according to claim 2, characterized in that the metal electrode consists of a plate in the form of a cylinder or a cone. k. Device according to claim 2, characterized in that the metal electrode consists of a grid which is of cylindrical or conical shape. 5. Device as claimed in claim 1, characterized in that the outer electrode is annular and consists of graphite and is integral with the central passage. 6. Device according to claim 2, characterized in that a contact with or at some distance from the outer surface of the electrode is provided with a high temperature resistant resistance. Device according to claims 5 and 6, characterized in that the space between the two electrodes is filled with gas. 8. Device according to claim 1, characterized in that the refractory mass is insulating and a coil surrounding the central passage of graphite 30 is embedded therein, the two ends being connected to an alternating current source. Device according to claims 1-8, characterized in that the central graphite passage at the mouth is provided with a liquid-cooled jacket. 8100433 -9- 10. Device as claimed in claim 9, characterized in that the cow jacket consists of a ring which is screwed onto the end of the tube. 11. Device as claimed in claim 9, characterized in that the cooling jacket consists of a cut in the form of a spiral, which is made directly in the central passage and which is sealed with a graphite sleeve in the form of a tube which can slide over the channels thus formed. 12. Device according to claims 1-11, characterized in that the graphite refractory system is surrounded by a metal sealing sleeve with a passage for gas from an annular chamber to the interior of the furnace. Device according to claim 12, characterized in that the gas is fed to a mixing chamber which is contained in the refractory mass and is sealed to the outside. Device according to claims 12 and 13, characterized in that the gas can flow from the mixing chamber to the interior of the oven along the wall of the metal sleeve and the bottom part of the graphite part. Device according to claims 1-11t, characterized in that it is fixed to the casting mold of the melting furnace by means of bolts provided with springs. 16. Device according to claims 1-15, characterized in that the free surface of the refractory mass is protected outwards by an insulating ring which is resistant to high temperatures. 17. Device according to claims 1-16, characterized in that the free end of the passage of graphite is protected by an annular cap of refractory material which can form the pouring funnel. 18. Device as claimed in claims 1-17, characterized in that a resistance for the indifferent gas is arranged in the form of a ring surrounding the pouring opening. Device according to claims 1-18, characterized in that the passage of graphite consists of two concentric parts at the location where the actual pouring channel is formed, which parts can be taken out separately. 8100433