EP0912271B1 - Liquid-cooled mould - Google Patents

Abstract

PCT No. PCT/DE97/00961 Sec. 371 Date Nov. 13, 1998 Sec. 102(e) Date Nov. 13, 1998 PCT Filed May 7, 1997 PCT Pub. No. WO97/43063 PCT Pub. Date Nov. 20, 1997A liquid-cooled chill mold for continuous casting of thin steel slabs is disclosed whose cross-sectional length is a multiple of the cross-sectional width, having two opposing wide side walls, each with a copper liner and a backing plate, and narrow side walls delimiting the width of the slab, with the copper liners that delimit the mold cavity being detachably attached to the backing plates by metal studs made of a CuNiFe alloy and the metal studs being welded to the copper liners.

Description

A liquid-cooled mold of the type in question becomes continuous casting of thin steel slabs, the cross-sectional length of which is a multiple of the Cross-sectional width. At least every broad side wall is made up of one Mold cavity bounding copper plate and a steel support plate together. The copper plate is on the support plate by means of transversely protruding metal bolts attached. To do this, the metal bolts penetrate the holes in the support plate. End The holes are provided with extended areas in which nuts on the Threaded ends of the metal bolts can be screwed. With their help Copper plate pulled tight to the support plate.

In the scope of US Pat. No. 3,709,286, it is known to tighten the metal bolts made of stainless steel form. However, stainless steel metal studs lead to poor welded connections with the copper plate, since coarse-grained structures form at the welds. These are not very elastic and therefore very sensitive to bending stress.

Through the Patent Abstracts of Japan JP-A-3258440 it is known, in the back holes of the mold room screwing in limiting copper plate and insert longer rods into these screw sleeves, which push a cool box across and attach the copper plate pull up the stainless steel support plate. There are also holes in the support plate intended. Next to it are on the back of the copper plate short fastening bolts by stud welding fixed. These short mounting bolts are with receiving sleeves provided, in the shorter, penetrating the cool box Rods are screwed in.

Starting from the prior art, the invention is based on the object of a liquid-cooled mold for high casting speeds, especially for the Near-dimensional steel casting, to create, where the strength problems clearly in the area of the connections of the metal bolts with the copper plates are reduced.

This object is achieved according to the invention in the features of the claim 1.

At the heart of the invention is the measure that specifically removes metal bolts from a Form CuNiFe alloy. Due to such, especially hard-drawn, Metal bolts are now significant strength increases with little scatter in strength achieved in the welded joints with the copper plate. This can be made of pure copper, for example SF-Cu, or of a high temperature resistant Copper alloy, e.g. B. a hardenable copper alloy with additives of Chromium and / or zirconium exist. The previously unsafe handling and the many influencing factors during welding that involve a 100% inspection bring, omitted.

According to a particularly advantageous embodiment is the metal bolt according to claim 2 CuNiFe alloy Mn added that there is a composition of CuNi30Mn1Fe.

According to a particularly advantageous embodiment, according to claim 2 the metal bolts made of a CuNi30Mn1Fe material.

To attach the metal bolts to the copper plates, this is useful in itself known stud welding processes used (claim 3).

To improve the strength and toughness of the welded joint, according to Claim 4 the metal stud using a filler metal the copper plates welded.

In particular, nickel is used as a filler metal (Claim 5). The filler metal can be used as a foil between the metal studs and the copper plates are inserted. It is also possible to use the copper plates to be provided with the filler metal at the connection points or also to coat the end faces of the metal bolts. It is also possible to use nickel rings Use the metal studs on the circumference as a filler metal.

In a further embodiment of the basic idea of the invention, point accordingly the features of claim 6, the copper plates of the broad side walls Groove-like grooves running parallel to the casting direction and covered by the support plates Coolant channels on. With the help of such coolant channels, increased heat transfer can be achieved be guaranteed from the pouring side to the cooling water, so that high Casting speeds can be driven. Cracks in the copper plates and damage to any surface coatings that may be present omitted. Coolant channels in the copper plates then reach in particular Use when the thickness of the copper plates is sufficient to be sufficient in cross-section to be able to introduce large coolant channels.

In order to be able to dissipate the heat intensively in the area of the metal bolts, too according to claim 7 provided that the copper plates next to the coolant channels parallel to the casting direction and in the vertical cross-sectional planes the metal bolt has extending cooling bores. Such cooling holes can be generated by mechanical deep drilling. Through this Cooling holes transferred coolant avoids a local in continuous casting operation Temperature rise of the copper plates near the connection areas of the Metal bolt with the copper plate.

The cooling bores are preferably arranged in the area of the bathroom mirror.

In case of using thin copper plates, which have a very good heat transfer ensure, the invention provides according to claim 9 that the support plates groove-like, parallel to the casting direction, covered by the copper plates Have coolant channels. There are then no coolant channels in the copper plates available. If necessary, a combination of coolant channels can also be used used in the copper plates and in the support plates.

To further increase the casting speed, the cross section is according to claim 10 of the mold cavity is larger at the pouring end than at the strand exit end Measured end.

In this context, it is also advantageous if according to claim 11 the mold cavity has multiple taper.

Finally, according to claim 12 at the pour-side end of the mold cavity a bulge may be provided which decreases in size in the casting direction. This Bulging serves in particular to hold a dip tube.

Figur 1

im Schema im vertikalen Längsschnitt eine flüssigkeitsgekühlte Kokille;

Figur 2

in vergrößerter Darstellung eine Teilansicht auf die Rückseite einer Kupferplatte der Kokille der Figur 1 gemäß dem Pfeil II der Figur 3;

Figur 3

in vergrößertem Maßstab einen Teil-Horizontalschnitt durch eine Breitseitenwand der Kokille der Figur 1 und

Figur 4

ebenfalls in vergrößertem Maßstab einen Teil-Horizontalschnitt durch eine Breitseitenwand gemäß einer weiteren Ausführungsform.

The invention is explained in more detail below on the basis of exemplary embodiments illustrated in the drawings. Show it:

Figure 1

in the diagram in vertical longitudinal section a liquid-cooled mold;

Figure 2

an enlarged view of a partial view of the back of a copper plate of the mold of Figure 1 according to the arrow II of Figure 3;

Figure 3

on an enlarged scale a partial horizontal section through a broad side wall of the mold of Figures 1 and

Figure 4

also on a larger scale, a partial horizontal section through a broad side wall according to a further embodiment.

1 in FIG. 1 is a liquid-cooled, only schematically illustrated Mold for continuous casting of thin steel slabs, not shown, whose cross-sectional length is a multiple of the cross-sectional width. The mold 1 has two multilayer broad side walls 2 lying opposite one another and two narrow side walls 3, also opposite one another, which form a mold cavity 4.

The broad side walls 2 are at the pour-side end 5 of the mold cavity 4 Bulges 6 provided along a partial height of the mold 1 down be steadily reformed. The cross section is at the end 7 of the strand exit of the mold cavity 4 rectangular and to the desired thin slab cross section aligned. The purpose of the two opposite bulges 6 consists of the space required for a dip tube, not shown for the supply of the molten metal.

As is clear from FIG. 3, each broad side wall 2 has the mold cavity 4 delimiting copper plate 8 and a steel support plate 9. In the Copper plate 8 are, as can also be seen in FIG. 2 drawn without the support plate 8 lets, parallel to the pouring direction GR, covered by the support plate 9 and groove-like coolant channels 10 to which cooling water can be applied.

Furthermore, Figures 2 and 3 show that parallel to the coolant channels 10 also extend cooling bores 11 which can be acted upon with cooling water. The cooling bores 11 run in the vertical cross-sectional planes QE of metal studs 12 made of CuNi30Mn1Fe, which are produced using the stud welding process using nickel rings 13 as a filler metal on the Back 14 of the copper plate 8 are attached. Push through the metal bolts 12 Bores 15 in the support plate 9. By screwing nuts 16 onto the thread ends 17 of the metal bolt 12, the copper plate 8 is used on the support plate 9 and committed to this. The nuts 16 are in enlarged end sections 18 of the holes 15.

The coolant is fed into the cooling bores 11 via the coolant channels 10, and expediently, as shown in Figure 2, via a branch 19 between a cooling hole 11 and the adjacent coolant channel 10.

Figure 3 also shows that the coolant channels 10 in addition to the cross-sectional planes QE of the metal bolts 12 deeper than the other coolant channels 10 are trained.

The arrangement of coolant channels 10 and cooling bores 11 in a copper plate 8 takes place when the copper plate 8 has a sufficient thickness D.

If, on the other hand, a thinner copper plate 8a is used, coolant channels 10a according to FIG. 4 are worked into the support plate 9a and through the copper plate 8a when fixing the copper plate 8a to the support plate 9a covered with the metal bolt 12.

Claims (12)

1. Liquid-cooled chill for continuous casting of thin steel slabs whose cross-section length is a multiple of the cross-section breadth, which chill comprises two facing broad side walls (2) each exhibiting a copper plate (8, 8a) and a supporting plate (9, 9a), and narrow side walls (3) bounding the continuous casting breadth, whereby the copper plates (8, 8a) bounding the mould cavity (4) are fixed detachably to the supporting plates (9, 9a) by means of metal studs (12) made of a CuNiFe alloy and the metal studs (12) are welded on to the copper plates (8, 8a).
2. Chill according to claim 1, characterised in that Mn is alloyed with the metal studs (12) made of a CuNiFe alloy, resulting in a composition of CuNi30Mn1Fe.
3. Chill according to claim 1 or 2, characterised in that the metal studs (12) are fixed to the copper plates (8, 8a) by means of the stud welding method.
4. Chill according to one of claims 1 to 3, characterised in that the metal studs (12) are welded on to the copper plates (8, 8a) using a welding additive (13).
5. Chill according to claim 4, characterised in that the welding additive (13) is nickel.
6. Chill according to one of claims 1 to 5, characterised in that the copper plates (8) of the broad side walls (2) exhibit slot-like coolant channels (10) running parallel to the casting direction and covered by the supporting plates (9).
7. Chill according to one of claims 1 to 6, characterised in that beside the coolant channels (10) the copper plates (8) exhibit cooling bores (11) running parallel to the casting direction (GR) and extending in the vertical cross-section planes (QE) of the metal studs (12).
8. Chill according to claim 7, characterised in that the cooling bores (11) are disposed in the bath surface area.
9. Chill according to one of claims 1 to 5, characterised in that the supporting plates (9a) exhibit slot-like coolant channels (10a) running parallel to the casting direction (GR) and covered by the copper plates (8a).
10. Chill according to one of claims 1 to 9, characterised in that the cross-section of the mould cavity (4) at the pouring end (5) is larger than at the casting exit end (7).
11. Chill according to one of claims 1 to 10, characterised in that the mould cavity (4) exhibits a multiple conicity.
12. Chill according to one of claims 1 to 11, characterised in that the mould cavity (4) at the pouring end (5) has at least one bulge (6) which becomes smaller in the casting direction (GR).

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