KR100512799B1 - Casting Nozzles for Thin Strip Casting Equipment - Google Patents

Abstract

The present invention relates to nozzles for thin strips, in particular strip steel foundry equipment. In such a casting facility, molten steel must be supplied onto a carrier from a nozzle forming a casting slot. The nozzle is arranged with at least one primary inductor and a secondary inductor. The secondary inductor is water cooled and protrudes into the area of the casting slot.

Description

Casting nozzle for thin strip casting equipment

The present invention relates to thin strips, in particular casting nozzles for thin strip steel casting plants.

DE 37 07 897 discloses a nozzle for casting thin strip steel. The nozzles form a movable carrier and neighboring back dams and front dams. A casting slot is bounded towards the carrier between the rear and preembankments. The circulating strip steel functions as a carrier.

Since such nozzles are generally made of refractory material that wears to some extent at high molten steel temperatures, the casting slots may be deformed during casting and must be replaced after a certain molding time.

1 is a longitudinal sectional view of an embodiment of a nozzle for a thin strip casting plant.

FIG. 2 is a plan view of another embodiment seen from a line A-A direction in FIG. 1.

It is an object of the present invention to provide an improved nozzle structure that minimizes wear and allows molten steel to be heated in the region of the casting slot.

The object of the present invention is achieved by a configuration characteristic of claim 1.

In the present invention, the nozzle is arranged with at least one primary inductor and at least one secondary inductor, wherein the at least one secondary inductor is water cooled and projects into the casting slot.

By using primary and secondary inductors as separate components for the formation of electromagnetic fields up to the molten steel region, on the one hand, the molten steel in the secondary inductor region does not reach the bulkhead of the primary inductor, resulting in an electric short circuit. have. On the other hand, the molten steel can be heated in the region of the outlet opening by allowing a current induced in the secondary inductor to induce a eddy current in the molten steel. Thus, the outflow opening is deformed by the projection of the solidified molten steel. In addition, an electromagnetic force is supplied into the molten steel to help prevent the molten steel discharge of the secondary inductor. The principle is used in the "cold crucible technique" to dissolve the metal in the water cooled crucible.

According to a preferred embodiment, the secondary inductor consists of a plurality of parts electrically isolated from each other. Thus each part functions as its secondary inductor.

According to another preferred embodiment, a plurality of molten steel outlet openings are designed which are located side by side in the width direction of the thin strip between the rear and preembankment.

The molten steel is thus distributed relatively uniformly by the casting slot width (thin strip width). The outflow opening is formed by the corresponding design of the rear bank in the conveying direction or the corresponding design of the front bank in the conveying reverse direction.

According to another preferred embodiment, the secondary inductor in the rear bank consists of a plurality of insulated parts having a supply and drain of cooling water, and the individual parts for forming the outlet opening of the molten steel are dovetailed or arrowed or It is designed to be straight. In particular, a flow guiding plate is formed inside the part, so that the flow guide plate is reliably reached within the head region of the part facing the casting slot on the part end facing the casting slot between the water inlet and the drain. To guide.

According to another preferred embodiment, the electrically insulated portion of the secondary inductor is arranged with a water supply and a drain of the coolant in the region of the premature, and the head region of the portion, i. In the above, the part is designed to be dovetail or arrow or straight for the formation of the outlet opening.

When referring to the dovetail type or the arrow shape in the pre-embankment or the post-embankment in the outflow opening region, the different designs are interpreted as semi-circular shapes and the like. Also included are corresponding designs of the preembankment and the afterembankment, for example the outflow openings being formed in a circle. The interior of the mutually insulated portions in the premise also preferably has a flow guide plate between the water inlet and the drain.

Fig. 1 shows a longitudinal cross-sectional view of the nozzle, in which the secondary inductor 22 is composed of individual portions whose ends are dovetail-shaped in the region of the rear bank 2. The cross section is a cross section of the center of the dovetail 23. On the carrier 1, in particular on a continuous strip circulating on a roller, a rear bank 2 is placed.

A casting slot 4 is formed between the rear bank 2 and the front bank 3. The secondary inductor 22 is adjacent to the primary inductor 21. Molten steel flows out of the back-flow region 5 in the solidification region 6 in the flow direction indicated by the arrow 7 in the space region between the dovetail 23 and the preembankment 3. Within the portion 22 a flow guide plate 24 is arranged. The secondary inductor 22 is covered with refractory material 25 towards the backflow region 5. The inductors 22 and 32 are water cooled and the inductor is preferably made of copper. High frequency is supplied to the primary inductor 21.

In the variant shown in FIG. 2, the preembankment 3 is formed by a plurality of secondary inductors 32 electrically isolated from each other, in which the primary inductors 31 induce a current. The primary inductor 31 and the secondary inductor 32 are water cooled and the high frequency is supplied to the primary inductor 31. The secondary inductor 32 reaches the end of the dovetail of the secondary inductor 22.

[Effects of the Invention]

According to the invention, the wear of the nozzle is minimized so that the molten steel can be heated in the region of the casting slot which is not deformed in shape.

Claims (5)

A casting nozzle for thin strip casting equipment having a rear bank placed on a carrier for thin strips movable in a transport direction, and a prembank bounding the casting slot for carriers in a transport direction, At least one primary inductor (21, 31) and at least one secondary inductor (22, 32), characterized in that the at least one secondary inductor (22, 32) is water cooled and protrudes into the casting slot (4). Nozzle made. 2. The casting nozzle of claim 1, wherein the at least one secondary inductor (22, 32) comprises a plurality of parts electrically isolated from each other. A plurality of outlet openings forming the casting slots 4 in the thin strip width direction between the rear bank 2 and the first bank 3 are formed in parallel with each other. Casting nozzle. 4. The at least one secondary inductor (22) in the rear bank (2) comprises an electrically insulated and water-cooled portion having a water supply and drain holes for cooling water, the portion being dovetailed or arrowed. Casting nozzles made of a straight or straight line. 4. The at least one secondary inductor (32) in the preembankment (3) comprises an electrically insulated portion having water supply and drain holes for cooling water, the portion being dovetailed or arrowed or straight. Casting nozzle.