EP1049551A1

EP1049551A1 - Receptacle for metallurgic melting

Info

Publication number: EP1049551A1
Application number: EP99902542A
Authority: EP
Inventors: Markus Schwan; Dieter Lobemeier
Original assignee: INTOCAST AG Feuerfest-Produkte und Giesshilfsmittel
Current assignee: INTOCAST AG Feuerfest-Produkte und Giesshilfsmittel
Priority date: 1998-01-22
Filing date: 1999-01-15
Publication date: 2000-11-08
Anticipated expiration: 2019-01-15
Also published as: ATE235980T1; JP3386794B2; WO1999037423A9; DE19802222C2; DE19802222A1; WO1999037423A1; ZA99359B; EP1049551B1; DE59904841D1; JP2002500956A

Abstract

A pouring ladle (100) for molten steel has a monolithic fire-resistant lining (8) of the base which comprises a continuous gradient sloping from all directions toward and up to the outlet (25). A deflecting element (30) has a convex arched upper side (33) which extends the useful life of the lining.

Description

Metallurgical smelting containers

The invention relates to a container for metallurgical melts according to the preamble of claim 1 and a form usable in the manufacture of such a container.

So-called ladles are used for the transport of molten steel or other molten metals in steelworks and foundries, which are to be understood as examples of such containers. The ladles are lined with refractory materials, whose tasks are to protect the ladle's steel jacket from the hot melt and to minimize the temperature loss of the molten metal through an insulating effect. The refractory lining, against which the aggressive melt is at a high temperature, must not release any components into the melt that would contaminate it.

In the recent past, the ladle has become an essential factor in secondary metallurgy

Treatment of the steel. This includes flushing in inert gases to create a stirring effect in the melt, blowing in aids such as lime dust for desulfurization, introducing and melting alloying elements and improving the degree of purity of the steel melt. When emptying a ladle, ie when the amount of up to 300 t has been poured off, as little steel as possible should remain on the bottom of the ladle, as this means a loss and solidifying steel structures when tilting the ladle to remove the slag are very annoying can.

From DE 197 38 709 A1 it is already known that the bottom area of a metallurgical vessel has an inclined surface towards the tap hole (spout), which prevents melt from standing on the bottom during emptying. However, nothing emerges from DE 197 38 709 AI about the type of refractory lining of the metallurgical vessel.

On the bottom of the lining of a ladle or other metallurgical vessel, depressions form in the impact area when the hot melt is filled in due to the erosion, which shorten the operating time and in which melt residues remain which impair the spreading.

In order to counteract this, it is already known from DE 34 43 281 AI to provide a convex impact element in the form of a bump surface at the point of impact of the pouring jet, which should avoid premature wear at the point of impact.

However, the refractory lining in this embodiment consists of molded refractory products. Molded refractory products are stones made by pressing, usually of a standardized format, and components of a customer-specific format formed by casting, stamping or vibrating. The contact surfaces of the stones with one another are optionally fire-resistant

Spread mortar. With different formats / - Components of the refractory lining of a steel ladle inevitably result in joints which have to be filled in by pounding or pouring suitable mortar or putty. This combination of materials with different physical properties causes additional stress on the refractory lining beyond the mere attack of the melt. In addition, shaped refractory components allow the shape of the floor to be varied only with considerable effort.

The invention has for its object to design a ladle such that the amount of melt remaining in the pan at the end is minimized.

This object is represented by the one in claim 1

Invention solved.

This is achieved through the interaction of three characteristics.

The slope known per se should initially be present from all directions towards the spout, namely over 360 ° with respect to the upright axis passing through the center of the spout. It is thereby achieved that there is no depression at any point on the top of the base in which a residual amount of the melt can remain. The

Steel is removed as far as possible from the bottom of the pan during normal pouring. This not only has the advantage that no problems with solidifying steel residues arise during the subsequent tilting of the pan, but also increases the output, namely by 0.3 to 7 t per

Pan, depending on their size.

As the number of casts progresses (number of batches), the reinforcement of the impact area given by the convex shape, which counteracts the formation of a depression, will flatten out, but can in any case also the initial convex shape, a considerable increase in the service life of the pan base can be achieved. The convex shape of the baffle element interacts with the rest of the design of the pan base in such a way that the steel striking the baffle element initially flows out of the baffle element in accordance with the curvature and then gets into the slope of the pan base, so that it flows over its entire flow path towards the spout extending overall gradient without recesses.

The production of the irregular shape of the bottom of the lining is made possible by the third feature of the monolithic lining of the same in a practicable manner, which also has the great advantage of a seamless and therefore low-attack surface. Monolithic refractory linings are e.g. B. known from DE 44 03 270 Cl. In such linings, flowable casting or vibration compounds are used in combination with corresponding templates and result in a seamless, freely shaping of the lining consisting of a uniform material.

In the preferred embodiment according to claim 2, the top of the impact element is designed as a flat curvature, which can be spherical, but need not be.

When emptying the ladle, the amount of residual melt remaining in the same must be minimized, but on the other hand it must be prevented in any case that portions of the liquid slag are poured out of the ladle, because inclusions of slag would render the casting or the cast steel unusable .

In this sense, the embodiment according to claim 3, by which it is ensured that towards the end of the pouring no large structures made of residual steel remain on the pan base.

From this point of view, it is advisable to proceed when casting using the container according to claim 4 described in claims 1 to 3.

According to studies by Hammerschmidt and Andrezejewski et al. In the book "Refractory delivery of the vessels for secondary metallurgy" published by Stahleisen, publisher Haus der Technik (1987), it can be ensured that no slag runs out at the end of the pouring. At the same time, due to the inventive design of the bottom of the lining in the ladle, no large amounts of residual steel remain. In the known ladles are in

Depending on the size of the pans, the inside diameter of the spout is usually 30 to 95 mm. With the previous processes, residual steel quantities in such pans between 0.3 t and 7 t were inevitable, depending on the pan size. In the inventive design of the floor in combination with the casting method of claim 4, these amounts of residual steel can be significantly reduced without entraining slag.

A mold for making the lining of the bottom of a

Container made of a flowable refractory material can be designed according to claim 5.

According to claim 6, the curved impact element can be connected to the bottom of the mold by a separate one

Be formed.

This not only simplifies the manufacture of the mold, but also makes it possible to use domes with different curvatures if necessary. It may be expedient, in accordance with claim 7, to provide a connection for a supply line of a fluid pressure medium in the bottom of the mold to support the lifting of the mold during demolding, as is known in a similar form from ZA-PS 94/8240.

Exemplary embodiments of the invention are shown in the drawing.

Fig. 1 shows a top view of a ladle for

Melting steel with finished lining;

Fig. 2 shows a longitudinal section through the upright ladle of the line II-II in Fig. 1;

Fig. 3 shows a corresponding section through the lower part of the ladle along the line III-III in Fig. 1;

Fig. 4 shows a corresponding section along the line IV-IV in Fig. 1;

Fig. 5 shows a longitudinal section through the lower part of the ladle according to the line II-II in Fig. 1 when forming the bottom by means of a template.

The casting ladle designated 100 as a whole in FIG. 1 consists of a pot-shaped steel housing 1 with a bottom 2 which is essentially horizontal in the operating position and an upright side wall 3 which diverges somewhat conically upwards. According to FIG

Ladle 100 a slightly oval floor plan. But this can also e.g. be circular. On the outside of the side wall 3 made of sheet steel, opposite horizontal pins 4 are attached, on which a hanging device 5 engages, on which the ladle

100 can be lifted on a crane. To empty the Slag after pouring the melt in the ladle 100, the ladle 100 can be tilted about the axis A of the pin 4.

The housing 1 of the ladle 100 is provided on the side wall 3 with a masonry refractory lining 6, the inner plates are designated by 7. The bottom 2 of the housing 1 also has a brick or cast permanent lining 8 which is held on the bottom 2 by anchors 9 so that it does not detach from the bottom 2 when the ladle 100 is tilted.

A monolithic lining 10 is provided on the inside of the permanent lining 6 of the side wall 3 in the fully lined ladle 100, which is only indicated in FIG. 2 by dash-dotted lines. Before the lining 10 of the side wall 3 is produced, the lining 20 of the base 2, which is at issue here, is produced. The lining 20 comprises a base 21 having the shape of a base plate and a side wall 22 which extends integrally thereon at the edge and extends over 3 to 20% of the height of the ladle 100 and with the base 21 is a one-piece monolithic molded part in the shape of a forms flat pots. The bottom plate of the lining 20 of the floor

2 can have a thickness of up to 80 cm for large ladles.

The top 23 of the bottom 21 is not flat, but has a certain relief, which is designed so that from each point of the top 23 from the way to the spout 25 has a slope, which over the entire distance, which is a certain volume element Melt has to travel from any point on the ladle over the bottom 21 to the spout 25, in the same direction. There are therefore no depressions in the surface 23 in which could stop the melt. The spout 25 represents the deepest point of the flow path for a volume element of the melt and is reached by the volume element without intermediate lifting.

In the exemplary embodiment, the spout 25, as can be seen from FIGS. 1 and 3, is close to the edge of the plan of the casting mold 100. The relief of the upper side 23 of the base 21 is therefore not symmetrical about an upright central axis, but rather points to that Side of the spout 25 on a fairly large slope, while the slope on the opposite side is much smaller. The relationships are to be illustrated by the fact that in FIG. 1 contour lines 29 of the top 23 of the base 21 are drawn. On the side of the spout 25 are the

Contour lines 29 close together, which indicates a steep gradient, while on the opposite side they are much further apart, i.e. the gradient is much smaller there. However, the relief is designed in such a way that the slope is directed in all directions over 360 ° around the axis B of the outlet 25 against the outlet 25, so that melt cannot remain anywhere.

The spout 25 (Fig. 3) includes one in the monolithic

Material of the bottom 21 embedded outlet nozzle 31 with an inner diameter 34. Starting from the upper edge of the outlet nozzle 31, a funnel 32 is formed in the bottom 21, which strives apart with an opening angle of approximately 60 ° upwards. If the pouring is then stopped when the melt is at a height 37, it is ensured that no slag is poured off and only a small volume of melt remains in the ladle 100. The height 37 is located a distance 35 above the in the edge 36 of the funnel 32 or the spout 25 located at the height 36. The distance 35 is at least as large as the diameter 34 of the spout 25. The uniform formation of the top 23 of the bottom 21 corresponding to the contour lines 29 is interrupted by a baffle element 30, which is formed by an elevation of the top 23 of the bottom 21, the top 33 of which is convexly curved and has an inclined boundary 26, 27 in at the edge the top 23 merges. The outline of the baffle element 30 is circular in the embodiment over approximately 240 ° (Fig. 1) and otherwise cut straight. The oblique boundary of the circular part bears the reference number 26, that of the straight part the reference number 27. The base of the oblique boundary 27 lies on a straight line 28 which runs approximately through the center of the plan of the ladle 100 and passes through the axis B of the nozzle 25.

The flat curvature of the upper side 33 of the impact element 30 can be part of a spherical surface, but it can also be another continuous convex curvature. The thickening of the base 21 in the region of the baffle element 30 resulting from the curvature makes it possible to extend the operating time of the ladle 100 until disruptive depressions have occurred due to the erosion of the hot melt impinging on it.

The shape of the top 23 of the bottom 21 is generated with the aid of a template 40 which is formed by a stable flat-pot-shaped molded part made of strong steel sheet (FIG. 5), which comprises an annular upright side wall 41 and a bottom plate 42, the underside of which Relief of the lining 20 is complementary. The mold 40 can be lowered into the ladle 100 by means of ropes or chains attached to the crane eyes 43, where it is secured against buoyancy. There then becomes the space between the outside of the mold 40 and the inner plate layer 7 of the permanent lining 6 or the upper side of the permanent lining 8 of the bottom 21 with a flowable refractory material represented by the cross hatching for up to a height 31 filled in, which corresponds to the upper limit of the side part 22 of the lining 20. For the formation of the baffle element 30, the mold 40 has a concave design, which can be formed by screwing a correspondingly crowned cap 48 onto the base plate 42 of the mold, the later baffle element 30 being located under the cap at the location of the later 48 is a perforation of the base plate 42, which is covered by the cap 46. To form the inclined boundaries 26, 27, bevels 46, 47 attached to the calotte 48 are used.

The attachment is carried out by means of welded-on angles 44 and screws 45, only one of which is shown in FIGS. 1 and 5, or in another suitable manner.

In the center of the calotte 48 or at another location on the base plate 42 there is a connection 49 for compressed air which, after the end of the molding, is introduced between the underside of the base plate 42 and the top side 23 of the base 21 and supports the lifting of the mold 40 . The connection 49 also enables the space under the cap 48 to be vented when filling the flowable refractory material.

Claims

Patent claims

1. container for metallurgical melts, in particular casting ladle (100) for molten steel, with a cup-shaped, open-topped housing (1) made of sheet steel with a bottom (2) and a right-hand side wall (3) during operation, with one the inside of the Housing (1) covering the melt-absorbing clear interior of the housing (1) determining refractory lining with a spout (25) provided for the melt in the bottom (21) of the lining and (2) of the housing (1), the upper side (23) of the bottom (21) of the lining in each plane, which passes through the upright axis (B) running through the center of the spout (25), a slope towards the spout (25) and a refractory impact element (30 ) has its top

(33) is convex and the bottom (21) of the lining consists of a monolithic refractory material.

2. Container according to claim 1, characterized in that the upper side (33) of the impact element (30) is designed as a flat spherical curvature.

3. Container according to claim 1 or 2, characterized in that the bottom (21) of the lining (20) in the region of the spout (25) one from the upper edge of the pouring nozzle (31) with an opening angle of 30 ° to 90 ° apart striving funnel (32) whose height (35) corresponds at least to the inside diameter (34) of the pouring nozzle (31).

4. Casting method using a container according to one of claims 1 to 3, characterized in that the melt is poured at the end of the casting only to the extent that a melt residue in a height (35) corresponding to the diameter (34) of the pouring nozzle (31) remains above the top of the spout (25).

5. Mold for producing the bottom (21) of a container according to one of claims 1 to 3, characterized in that it consists of a shaped body made of sheet steel in the shape of a low open pot, which can be lowered into the container on a crane and at the

Underside of its base plate (42) which has a corresponding complementary relief to the top (23, 33) of the base (21) of the lining (20).

6. Form according to claim 5, characterized in that the

Mold (40) in the region of the impact element (30) has an opening (36) corresponding to its outline, which is covered by a domed cap (48) which can be connected to the base plate (42) of the mold (40) at the edge of the opening (36) is.

7. Mold according to claim 5 or 6, characterized in that in the bottom (42,48) of the mold a connection (49) for a feed line of a fluid pressure medium to support the lifting of the mold (40) from the bottom (21) of the lining (20) is provided during demolding.