EP1506827A1 - Casting system and method of casting non-ferrous metals - Google Patents

Abstract

Apparatus for casting non-ferrous metal melts, especially copper or copper alloys comprises a tundish (1) having an immersion pipe (6) running downward at an angle with a first section (8) and a second section forming the tip (9) of the immersion pipe. The immersion pipe is sealed at one end and has an outlet opening effecting a first directional change of the melt flow. A lip covering the outlet opening is arranged on the immersion pipe tip at a distance from the outlet opening and leads to second directional change and distribution of the melt flow across the longitudinal axis of the mold. The outlet opening and the lip are located above the mold bath surface in the operational state.

Description

The invention relates to a casting system for casting non-ferrous molten metals, in particular copper or copper alloys, for the manufacture of flat products, consisting of a tundish with at least one, preferably obliquely downwardly extending dip tube, which in the in a thin-slab mold immersed melt bath, as well as a method for Shed.

Immersion tubes for introducing a molten metal into a mold are already known in various designs. The Tauchgießrohre should ensure a uniform and low turbulence distribution of the melt in the mold. Furthermore, contact with the melt flow below the bath surface with atmospheric oxygen should be prevented by the use of dip tubes. The prevailing in the tundish hydrostatic pressure is exploited to give the melt the required flow rate. The flow rate increases depending on the casting angle. When used in practice Tauchgießrohren showed that a negative pressure is generated by the increasing acceleration of the melt in the dip tube, and thereby turbulence in the melt contained in the mold arise and as a result Badspiegelschwankungen occur. In addition, in the casting of metal, especially copper or copper alloys, a variety of chemical and physical processes take place, in particular an intensive interaction between the gaseous and solid components of the melt. These boundary conditions are influenced, among other things, by the temperature profile and the melt pressure. If a negative pressure arises in the submersible pouring tube, it may cause the release of melted gaseous substances such as hydrogen and SO ₂ . By the escape of gases, there is the danger that form during the solidification phase of the melt porous areas that adversely affect the quality of the final products.

To avoid flow suppression in a pouring tube is in the DE 40 34 652 A1, the cross section of the flow opening on To keep inlet end of the pouring tube by means of a narrowing smaller than the cross section the flow opening at the outlet end of the spout to one opposite build up the pressure in the melt stream at atmospheric pressure. Of the Spout of the metallurgical vessel and the pouring tube are over a conical Seal set interconnected.

In DE 197 38 385 C2 a Tauchgießrohr is described which at its lower End has a bottom element and at least two lateral outlet openings above the floor element. On the inner wall of the dip tube are special flow guide.

A submersible pouring tube with a funnel-shaped design arranged at the tube end Verwirbelungskammer is known from DE 101 13 026 A1, wherein at the transition from Pipe section to Verwirbelungskammer a tear-off edge is provided.

EP 0 925 132 B1 discloses an immersion casting tube for the continuous casting of thin slabs known as a pipe with a circular cross-section, in vertical Arrangement, is connected to the ladle. The pouring tube is at its lower End with a flattened distribution area, a so-called diffuser, formed, which dips into the melt of the mold. In the diffuser is an in Direction of flow tapered separating body arranged through the two partial flows be formed. The cross section of the diffuser is smaller above the separating body as the cross section of the upper pouring pipe section.

The side walls of the diffuser diverge at the same angle as the outside Side walls of the separator inside. By the measures provided Vortex and turbulence in the bathroom mirror should be avoided. The disadvantage is that the melt flow still reaches deep into the bath of the mold, and thereby the degassing takes place inside the mold bath. The from the known prior art Tauchgießrohre are for the vertical Casting, in particular of molten steel, intended for relatively thick slabs. Of the Melt flow is in the shortest path, in the vertical direction, in the Kokillenbad injected and usually only shortly before entering the mold bath fluidly affected.

The invention is based on the object of a casting system for casting non-ferrous metal melts, especially copper or copper alloys, to create that one trouble-free introduction of the melt into the mold and a degassing at the ensures a free surface of the mold, the formation of a negative pressure in the Immersion tube avoids and is characterized by a simple structural design distinguished. Furthermore, a suitable method for casting non-ferrous molten metals be created.

According to the invention, the object is achieved by the features specified in claim 1 solved. Suitable embodiments and developments are the subject of Claims 2 to 14. The proposed procedure is in claim 15 indicated and corresponding embodiments in claims 16 and 17.

The casting system is designed so that the in the tundish molten metal, preferably obliquely down, in the lower-lying Mold flows.

The casting angle can be in a range of 2 ° to 90 °. At the in departure direction pointing end face of the distribution vessel is at least one obliquely downward, in arranged given pouring angle extending dip tube. For pouring in the Width larger flat products, which are in their width ≥ 1.5 H, where H is the height or Thickness can, in the distribution vessel also several identical dip tubes in predetermined intervals adjacent to each other.

The dip tube consists of a first section with a preferably in Flow direction of the melt continuously tapered inner wall and a second section that forms the dip tube tip. The inner wall of the first Section does not necessarily have to be rejuvenated and can be different have appropriate geometric design. Optionally, at the first Section, before the onset of rejuvenation nor a short tubular fitting be arranged. This or the initial section of the first section are is poured in a use of refractory concrete of the distribution vessel. Of the The first section extends from the distribution vessel to directly to the bath surface the mold. The rejuvenation leads to a change in cross section with a decreasing cross-sectional area. The rejuvenation can be formed differently. Starting from a circular cross-section at the The beginning of this section is e.g. by pushing a tube flat one Forming in a cross-sectional shape at the end of the section the shape of a Langloches has. The deformation can also be done so that the cross-sectional shape at the end of the section elliptical or the entire section as hexagonal Rejuvenation is formed. Another variant is a conical version of this Section. This section closes in the melt bath of a mold submerged dip tube tip. This is closed at its free end, e.g. by means of a plug, and has at its towards the mold base facing wall at least one, a first change in direction of the melt flow causing discharge opening, which in the operating state below the Kokillenbadoberfläche is located.

The entire dip tube can be made of a piece of pipe, wherein the Dip tube tip is formed in the same way as the previous one Section and at the end an elliptical or circular cross section or a Has cross-section in the form of a slot. About the length of the dip tube tip Thus, the cross-sectional shape changes to a small extent.

It is also possible, the dip tube tip as a separate component with a almost constant or decreasing cross-sectional area to produce and on to fix the deformed section, z. B by welding. In this case it is possible to form the section conical and at this a dip tube tip with attach a slot shape, the dip tube tip a short transition section for the transition from the circular cross-sectional shape in the slot shape has. The formed as a separate component dip tube tip can also be made of a different refractory material than the itself rejuvenating section.

If the dip tube tip is formed in cross section as a slot, so should the two opposite parallel wall sections a distance of at least one Third of the diameter of the cross section at the beginning of the tapered trained Have section of the dip tube.

The located at the bottom of the dip tube tip discharge port for the Melt is preferably formed as a slot. In place of a long hole can also have two circular openings, immediately one behind the other, be arranged.

In the first section of the dip tube is characterized by the continuously decreasing cross section ensures that the melt in constant contact with the Inner wall of the dip tube is and in the dip tube no air bubbles or cavities can form. The length and the degree of rejuvenation of this Sections are of the properties of the molten metal and the respective Casting angle dependent. The dip tubes have a constant wall thickness.

Since the melt in the dip tube tip can not flow off in the axial direction, the free end of the dip tube tip is closed, takes place at the level of the discharge opening or the outflow openings a first deflection of the melt flow order at least 90 °, based on the casting angle. The melt flow forced change of direction is essential to a gentle initiation of To ensure melt in the mold. Preferably, the cross-sectional area should the outflow opening or the sum of the cross-sectional areas of the outflow openings 80% to 98% of the cross-sectional area of the dip tube tip amount. In For certain applications, this can be greater than 100%. The cross-sectional shape the outflow openings can be designed differently.

The immersion tube should be fully filled with melt during operation and during the Casting process, the melt should not from the inner wall of the dip tube can replace. As a result, there is a risk of a negative pressure excluded and in the melt, there may be no undesirable degassing come. By the intended deflection or change in direction of the melt Upon entry into the melt bath, a so-called "shot-in" of the melt and thus prevents excessive formation of bubbles.

Furthermore, it is provided as an essential feature that below the discharge opening or outflow openings a lip covering this overlapping is arranged. This will cause a second change of direction of the melt flow achieved. The lip is dimensioned in its dimensions so that the tread surface is equal to or greater than the discharge opening. The lip is in a defined arranged parallel distance or inclined to the discharge opening, preferably should be at least 5 mm. In an inclined arrangement, the distance is at its largest point at least 5 mm. In the operating state are the Outlet openings and the lip completely below the Schmelzenbadspiegels the mold.

The melt emerging from the outflow opening first hits the lip slowed down, and again deflected by at least 90 ° and laterally distributed in the melt bath. This second, second, change of direction causes a particularly gentle introduction of the melt into the mold. The division of the Melt after hitting the lip in two laterally directed streams favors the migration of still existing bubbles to the bath surface of the mold. In Practical tests have shown that the measures mentioned above Flow rate of the molten metal on entering the melt a value of ≤ 0.5 m / s can be reduced.

According to the proposed procedure, it is crucial that the speed of the melt flow increasing as a function of the casting angle reduced in the dip tube and prior to introduction into the melt bath the mold is slowed down and the melt flow at least twice in their Flow direction is deflected by at least 90 °.

The combination of this two-time change of direction of the melt before the Introduction into the melt bath leads to a significant reduction in the flow rate in the order of about 50%.

By the lateral, transversely to the longitudinal axis of the mold taking place the introduction of two Partial streams split melt is achieved, that in the area of the mold wall melt constantly in contact with hot melt in contact and Consequently, no solidification film can form. It also avoids that hot melt hits directly on the mold wall. Possibly still existing Gas bubbles can escape directly at the mold wall.

The measures according to the invention lead to a significant improvement in quality the microstructure of the semi-finished products to be produced. Unwanted inclusions of Gas or air bubbles are avoided. Due to the two-time change of direction the melt and thereby causing significant reduction in Flow rate before introducing the melt into the mold Damage to the mold walls largely avoided.

The tapered portion and the dip tube tip of the dip tube are preferably made of one and the same heat-resistant material, but can also be made of different ones Be made of materials such. a combination of ceramics and made of metal. For the starting process, it is advantageous if the dip tube with a additional heating means, e.g. an electrical resistance heating, equipped.

The proposed casting system makes it possible to produce thin-walled strips of non-ferrous metals, especially copper and copper alloys, with an excellent Produce quality.

In a vertical arrangement of the dip tubes has the dip tube tip at least two opposing outflow openings, each of a spaced-apart lip are covered, so that the melt flow is deflected twice by at least 90 ° before being introduced into the mold bath, and is significantly reduced in their speed.

Fig. 1

das Gießsystem in vereinfachter Darstellung als Längsschnitt,

Fig. 2

eine erste Ausführungsvariante eines Tauchrohres in perspektivischer Darstellung,

Fig. 3

die Einzelheit "X" gemäß Fig. 2 in vergrößerter Darstellung,

Fig. 4

die Vorderansicht des Tauchrohres gemäß Fig. 2 in vergrößerter Darstellung,

Fig. 5

eine zweite Ausführungsvariante eines Tauchrohres in perspektivischer Darstellung,

Fig. 6

eine Tauchrohrspitze mit einer geneigten Lippe als Längsschnitt und

Fig. 7

eine Tauchrohrspitze als separates Bauteil mit angeformter Lippe in perspektivischer Darstellung.

The invention will be explained in more detail below. In the accompanying drawing show

Fig. 1

the casting system in a simplified representation as a longitudinal section,

Fig. 2

a first embodiment of a dip tube in perspective view,

Fig. 3

the detail "X" of FIG. 2 in an enlarged view,

Fig. 4

the front view of the dip tube of FIG. 2 in an enlarged view,

Fig. 5

a second embodiment of a dip tube in perspective view,

Fig. 6

a dip tube tip with an inclined lip as a longitudinal section and

Fig. 7

a dip tube tip as a separate component with molded lip in perspective view.

In Fig. 1 is a casting system for casting copper strip by means of a strip casting mold represented, which is also referred to as casting with revolving mold. To from the melting of copper, it passes from the casting furnace into the tundish 1, which is in the example shown equipped with a spout 2. Depending on the Width of the belt to be cast in the casting spout 2 are several identical Immersion tubes 6 are arranged side by side in a defined casting angle of about 10 °, e.g. 6, 8 or 10. The distances between the individual dip tubes 6 can be different be. In the view shown in Fig. 1 only one dip tube 6 can be seen. The Diving tubes 6 are with their cylindrical connector 7 (Fig. 2) in an insert poured from refractory concrete, which is part of the distribution vessel 1. The Mold 3 is between the circumferential Kokillenoberband 4 and the circulating Kokillenunterband 5 arranged, each by means of drive and pulleys are curious. In Fig. 1, only the two front pulleys 4a and 5a shown. Also, the side walls and back wall of the mold, which can reach a height of up to 70 mm can not be seen in the drawing. The casting system is Part of a plant for the continuous production of copper strips. In the X marked line is the longitudinal center axis of the mold. 3 The copper melt located in the tundish 1 flows through the adjacent hydrostatic pressure through the dip tubes 6 in the mold 3. Due to the process inclined arrangement of the dip tubes 6, in a predetermined casting angle, the flow rate of the copper melt is influenced.

Immediately after the relatively short connector 7 with a circular cross-section begins the continuously tapered in the flow direction section 8 the dip tube 6 extending from the spout 2 to the bath surface of the mold 3 extends. The front part of the dip tube 6, the dip tube tip 9, dives in Operating state completely in the melt bath of the mold 3 a.

In the figure 2 is a first embodiment of a dip tube 6 as a single part shown enlarged. The dip tube 6 has a cylindrical connection piece 7, on followed by a continuously tapering section 8 in the flow direction, which has a diameter D1 immediately at the beginning, which is equal to the diameter of the connecting piece 7 is identical. To the section 8 with the length L1 closes the dip tube tip 9 with the length L2 on. The ratio of L1: L2 is e.g. 8.3. The connecting piece 7, the section 8 and the dip tube tip 9 are made of a tubular piece made of heat resistant metal that in the area of Section 8 and the dip tube tip 9 continuously by pressing flat in one Tool is formed, with the section 8 in the beginning still a circular Cross-section D1 has, in the flow direction increasingly by a deformation merges in a plane in a defined slot shape, at the end of the dip tube tip 9 is reached (Fig. 4). This deformation becomes a continuous one Taper, a cross-sectional change with a reduction in cross-sectional area, reached. The cross-sectional area at the end of the dip tube tip 9 is about 1/3 smaller than the cross-sectional area with the diameter D1 at the beginning of Section 8. The formed at the end of the dip tube tip 9 slot 10 is through a welded closure plug 11 or in any other suitable manner locked. As clearly seen in Fig. 3, the slot 10 is by two each other opposite parallel straight wall sections 10a, 10b and two formed semicircular wall sections 10c, 10d, wherein the distance at least one third between the two straight wall sections 10a and 10b the diameter D1 of section 8 is, in the present example it is approx. 10 mm.

At the operating state in the direction of Kokillenunterband 5 facing, even Wall section 10a of the dip tube tip 9 is a slot-like outflow opening 12th introduced for the exit of the molten copper. As part of practical experiments has it turned out to be an advantage if they were preferably 90% to 98% the cross-sectional area of the flow cross-section at the end of the dip tube tip. 9 is. Instead of a slot 12 can also have two circular outflow openings 12a and 12b are arranged directly behind one another, as shown in FIG. 7 is shown.

The outflow openings 12 and 12a and 12b are connected by a parallel Lips 13 is covered, wherein "cover" in this case means that the lip 13th their width dimension is equal to or greater than the opening width of the elongated hole 12th or the diameter, in an arrangement of circular outflow openings. In the embodiment according to FIG. 3, the lip 13 is with its spacers 13a welded to the dip tube tip 9. The distance between the discharge opening 12 and the lip 13 should be at least 5 mm.

In Fig. 5, a further variant of a dip tube 6a is shown, with a continuous conical formation of the section 8 and the dip tube tip 9, starting from Diameter D1 of the continuous by reducing the circular cross-sectional area reduced to a diameter D2 to the end of the dip tube tip becomes. The circular opening of the Tauchrohspitze 9 is through a plug 11th locked. The difference between the diameter D1 and the diameter D2 is about 45%. The outflow opening for the melt and the lip 13 are formed analogously as in the embodiment variant shown in Fig. 2. Compared to the dip tube shown in Fig. 2 have this no separate connector. In the immersion pipe tip 9 shown in Fig. 6, which is the discharge opening 12 overlapping Lippe 13 arranged inclined. By the spacer 13 a is the lip 13th arranged at a distance 5 mm to the wall of the dip tube tip and runs diagonally upwards, to the end of the dip tube tip. The lip 13 is at the dip tube tip welded. Otherwise, this dip tube tip is analogous to how the dip tube tip of the dip tube shown in Fig. 2.

In Fig. 7 a formed as a separate component immersion tube tip 9 a is shown on the end of a conically extending portion of a dip tube accordingly the embodiment shown in Fig. 5 can be plugged and by welding this is attached. The dip tube tip 9a has a constant cross section in FIG Form of a slot 10, which at the end pointing in the flow direction by a Plug 11 is closed. At the opposite end, the dip tube tip 9a a transition piece 14, for the transition from the slot shape to the circular Shape, fitting to the appropriate section 6 of the dip tube Voted. At the bottom of the dip tube tip 9a are two in a row arranged outflow openings 12a and 12b, which through a parallel extending lip 13, 13a are covered. The lip 13 is at the dip tube tip 9a molded, which can be prepared as follows.

The tube tip of the dip tube, which in the raw state has a circular cross-section is in a pressing tool by a "flat press" reshaped to the desired cross-section in the form of a "slot", with a short Transition portion 14 of the circular shape in oblong shape is formed. Then takes place in a the length of the lip corresponding distance from Tube end a cross-sectional separation without completely cutting through the tube, and a longitudinal section to the cross-sectional joint. The pipe tip has now a longitudinally pointing lip. Thereafter, the holes 12a and 12b introduced for the outflow openings of the melt. Subsequently, the Opening the elongated hole 10 at the end of the tube tip by welding a Closure cap 11 closed. Thereafter, the protruding lip in the direction of introduced outflow openings bent, such that these the outflow openings Covered 12a and 12b in the designated distance. The lip 13 has a length of about 80 mm and is with its opposite to the flow direction pointing end to the adjacent wall portion of the dip tube tip 9a welded.

In order to avoid a deflection of the dip tubes in the operating state, can these are equipped with additional stabilization, e.g. one or more Stiffening ribs.

The inventive design of the dip tubes is in practical use the inclined flow of copper melt from the tundish into the mold is very favorably influenced. The conditional by the inclined arrangement of the dip tubes increasing flow velocity of the melt is due to the two times Change of direction of the flow so reduced that a gentle introduction into the Mold bath is guaranteed.

The continuous taper, in particular of section 8, with a change in cross section and reducing the cross-sectional area, causes the Melt on the inner wall of the dip tube rests and in the dip tube no Air bubbles or cavities may arise. This also applies to the dip tube tip 9, 9a, due to the change made in the cross-sectional shape (Circle / slot) or the continuing further rejuvenation. Because the end of Dip tube tip 9, 9a is closed, the melt is a deflection imposed at least 90 °, leading to a first reduction in the flow rate leads.

It is essential that by the arrangement of the outflow or the outflow at the bottom of the dip tube tip 9 a deflection or a first Direction change is achieved by at least 90 ° of the melt stream and additionally by the arrangement of the lip 13 below the outflow openings yet a second change of direction or deflection of the melt flow in lateral Direction, combined with a further reduction of the flow velocity. The melt flow is uniform and on both sides of the lip 13 significantly reduced flow velocity below the bath level of the mold introduced into the melt bath. The flow rate of the melt can thus reduced to a value of ≤ 0.5 m / s and does not shoot with high Speed, as is the case with conventional dip tubes, in the mold. This significantly reduces the formation of bubbles and any remaining bubbles can escape on the side walls of the mold so that formation of air or gas inclusions in the slab is avoided. Furthermore, a unwanted injection of the melt deep into the mold prevented. The melt flow is injected immediately below the surface of the melt bath and can degas there, leaving a smooth surface during the solidification process can train. There is no swirling of the melt in the area of Bath surface instead. The thus made introduction of the melt in the Kokillenbad also eliminates the risk of damaging the mold walls.

Claims (17)

Casting system for casting non-ferrous molten metals, in particular copper or Copper alloys, consisting of a tundish (1) with at least one arranged on this, preferably obliquely downward, in a defined casting angle, extending dip tube (6, 6a) with a first Section (8) and a second section forming the dip tube tip (9, 9a), immersed in the melt bath of a mold (3), wherein the dip tube tip (9, 9a) is closed at its free end (10, 11) and at its in the direction of Kokillenunterseite (5) facing wall at least one, a first change of direction the melt flow causing outflow opening (12, 12a, 12b) has, and at the dip tube tip (9, 9 a), spaced from the outflow opening (12, 12a, 12b), a lip (13, 12a, 12b) covering the outflow opening (12, 12a, 12b) 13a), which leads to a second change of direction and distribution of Melting flow transverse to the longitudinal axis of the mold (3), wherein in Operating state, the outflow opening (12, 12a, 12b) and the lip (13, 13a) located below the Kokillenbadoberfläche. Casting system according to claim 1, characterized in that the lip (13) is arranged parallel to the outflow opening (12, 12a, 12b). Casting system according to one of claims 1 or 2, characterized in that the lip (13, 13a) inclined to the outflow opening (12, 12a, 12b) is arranged. Casting system according to one of claims 1 to 3, characterized in that the outflow opening is formed as a slot (12). Casting system according to one of claims 1 to 4, characterized in that the cross-sectional area of the outflow opening (12) or the sum of the cross-sectional areas of the outflow openings (12a, 12b) 80% to 98% of the cross-sectional area (10) at the end of the dip tube tip (9, 9a ) amount. Casting system according to one of claims 1 to 5, characterized in that the distance between the outflow opening (12, 12a, 12b) and the overlapping lip (13) at its largest point (13a) is at least 5 mm. Casting system according to one of claims 1 to 6, characterized in that the first section (8) has a continuously tapering in the direction of flow of the melt inner wall. Casting system according to one of claims 1 to 7, characterized in that the tapered portion (8) at its beginning (D1) has a circular cross section and at its end a cross section in the form of a slot. Casting system according to one of claims 1 to 8, characterized in that the portion (8) is conical. Casting system according to one of claims 1 to 9, characterized in that the dip tube tip (9) is further continuously tapered in the flow direction. Casting system according to one of claims 1 to 10, characterized in that the dip tube tip (9a) is formed as a separate component and at the end of the tapered portion (8) of the dip tube (6) is fixed. Casting system according to one of claims 1 to 11, characterized in that , length and taper of the dip tube (6, 6a), depending on the casting angle, are matched to one another that the flow velocity of the molten metal after striking the lip (13, 13a ) ≤ 0.5 m / s. Casting system according to one of claims 1 to 12, characterized in that the dip tube (6, 6a) is equipped for heating with an electrical resistance heater. Casting system according to one of claims 1 to 13, characterized in that the section (8) and the dip tube tip (9) of the dip tube (6) consist of different refractory materials. Method for casting non-ferrous molten metals, in particular copper or copper alloys, from a tundish (1) by means of a dip tube (6, 6a) running at a defined casting angle, preferably obliquely downwards, into the molten bath of a mold (3), in particular with a casting system according to one of the preceding claims, characterized in that the increasing speed of the melt flow is reduced by at least two changes in direction of the melt flow, by a respective deflection by at least 90 °, to a considerable extent. A method according to claim 15, characterized in that the melt flow is divided after the first change in the flow direction into two laterally distributing sub-streams and thereby deflected a second time by at least 90 °. Method according to one of claims 15 or 16, characterized in that the melt flow through the geometric design of the dip tube (6, 6a) is influenced so that the dip tube (6, 6a) is fully filled in the operating state with melt and the melt is constantly in Contact with the inner wall of the dip tube (6, 6a) is and the flow rate of the molten metal is reduced so that it is ≤ 0.5 m / s during the entry into the molten bath of the mold (3).

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