EP1317978B1 - Mould pipe for continuous casting of metals - Google Patents

Abstract

Mold tube has a tube wall (2) with an inner contour (3) in a beam-blank format with rounded transitions (6) between wall sections (9) delimiting a flange region (7) on one side and a web region (8) on the other side. The inner contour can be directly cooled by a cooling medium introduced from the outside. Cooling channels (4) are provided in the tube wall extending in the longitudinal direction. The distance from two cooling channels next to each other in the transitions is less than the distance in the remaining wall sections. <??>Preferred Features: A water guiding casing fitted to the tube wall is provided on the outer contour. The tube wall has a double T-shaped cross-section.

Description

The invention relates to a mold tube for the continuous casting of metals according to the features in the preamble of patent claim 1.

To dissipate the heat generated during the continuous casting of metals, it is known to install a mold tube in a water-conducting jacket. In this case, care is taken that due to the inner dimensions of the Wasserleitmantels one hand, and the outer dimensions of the Kokillenrohrs on the other hand, a thermally well-defined gap is formed through which flows from bottom to top cooling water, which absorbs the heat accumulated and transported away. If a mold tube in the beam blank format used, so must the inner contour of the water jacket corresponding to the outer contour of such a format.

The removal of heat by means of the cooling water is largely determined by the water velocity in the gap between the mold tube and the Wasserleitmantel. However, this gap increases with each recalibration of a Kokillenrohrs due to the wear-related wear and thereby inevitably caused reduction in the wall thickness of a Kokillenrohrs. The enlargement of the water gap is, however, associated with a reduction of the water velocity and consequently also with a reduction of the heat dissipation.

From GB 954 719 it is known to provide molds for the continuous casting of metals with cooling holes which extend both in the longitudinal direction and in the transverse direction of the mold tube. In mold tubes in the beam blank format, however, the problem arises that cooling holes can be introduced transversely to the longitudinal extent only with great effort in the mold tubes. In addition, with the special geometry of the beam-blank format, extreme local heat loads occur in the transitions between, on the one hand, a flange region and, on the other hand, a wall region delimiting wall regions. In the case of unfavorable geometrical conditions of the transitions, this local heat load leads to overheating of the mold tube and to a drastic reduction of its service life.

The invention is - based on the prior art - the object of the invention to provide a mold tube for the continuous casting of metals, which has an improved life and in which local overheating be avoided.

A first solution of the problem consists in the features of patent claim 1.

According to the features of claim 1, the distance between two adjacent cooling channels in the transitions is smaller than the distance between adjacent cooling channels in the other wall sections.

This initially has the advantage that a to be matched to the outer contour of a tube mold water jacket can be omitted in principle. This significant reduction of the manufacturing effort is particularly noticeable in the case of a mold tube in a beam blank format.

By dissipating the heat through the cooling channels in the pipe wall, no changing heat removal conditions arise more. The number of recalibrations has no influence on the cooling capacity.

The cooling channels can basically emerge in all wall sections on the end faces of the pipe wall. In these areas, it is easily possible for a trouble-free installation and a secure sealing of a mold tube after recalibration to perform welds, which are then post-recalibrated easily to Neumaß.

If the cooling channels are provided with a round cross section, there is the further advantage after bending a tube mold to a beam blank format, that in this case also the cross sections of many cooling channels are deformed oval, in the sense that the surface areas for Enlarge pouring channel, so that can be expected with a higher heat dissipation.

A second Lössung consists in the features of claim 2. Thereafter, it is also possible to provide cooling channels only in the rounded transitions, while the remaining wall sections and the rounded transitions are cooled by a matched to the outer contour of the pipe wall Wasserleitmantel. In this solution, not the entire pipe wall is interspersed with cooling channels. Rather, cooling holes are present only in the areas in which local overheating would lead to a reduction in the service life of the mold tube. By combining a water jacket with introduced into the rounded transitions of the pipe wall cooling channels local overheating in the rounded transitions can be avoided and the life of the mold tube can be increased.

It is according to the features of claim 3 also possible to provide a Wasserleitmantel and at the same time both in the rounded transitions and in the other wall sections of the pipe wall cooling holes, wherein the distance of two mutually adjacent in the transitions cooling channels is smaller than the distance in the rest wall sections.

The cooling channels provided in the transitions may extend from the upper end side of the pipe wall to approximately the middle height region of the pipe wall. As a result, a more intensive heat dissipation in locally thermally stressed wall sections provided (claim 4).

According to claim 5, it is provided that in the outer contour of the pipe wall connected to the cooling channels Kühlmediumzuführungen and Kühlmediumabführungen are provided. These can be particularly advantageously provided in the middle height range on the outer contour of the pipe wall (claim 6). To form a cooling channel system, the cooling channels introduced from the end faces of the tube walls are closed and connected to one another by overflow channels.

To cool the mold tube, it is basically possible to connect the cooling medium supply and cooling medium discharges to a separate cooling circuit. Advantageously, however, the cooling medium flowing between the pipe wall and the water-conducting jacket can also flow through the cooling channels and ensure intensive heat dissipation in areas subjected to higher thermal stresses (claim 7). In order to facilitate the coolant inlet from the gap between the Wasserleitmantel and the pipe wall in the cooling channels, suitable conductive means may be provided on the outer contour of the pipe wall and / or the Wasserleitmantel, which direct the flow of the cooling medium in the cooling channels.

The features of the invention are particularly advantageous in a mold tube with a double-T-shaped cross section according to claim 8 noticeable.

The mold tube is preferably made of copper or a copper alloy.

Figur 1

den oberen Endabschnitt eines Kokillenrohrs im Beam-Blank-Format in der Perspektive;

Figur 2

das Kokillenrohr der Figur 1 in etwas verlängerter Darstellung in einer anderen Perspektive und

Figur 3

den oberen Endabschnitt eines Kokillenrohrs im Beam-Blank-Format gemäß einer weiteren Ausführungsform.

The invention is explained in more detail with reference to an embodiment illustrated in the drawings. Show it:

FIG. 1

the upper end portion of a mold tube in beam blank format in perspective;

FIG. 2

the mold tube of Figure 1 in a slightly extended view in a different perspective and

FIG. 3

the upper end portion of a mold tube in the beam blank format according to another embodiment.

1, a mold tube in the beam blank format is designated in FIGS. 1 and 2.

The mold tube 1 has a double-T-shaped cross-section with a constant over the entire circumference thickness D of the tube wall. 2

The inner contour 3 of the mold tube 1 determines the cross section of the cast strand.

In order to dissipate the heat generated during casting, 1 cooling channels 4 are provided in the tube wall 2 extending over the entire length L of the mold tube 1, which are acted upon in accordance with the arrow KW from bottom to top with cooling water. That is, the cooling channels 4 terminate in the end faces 5 of the tube wall 2, wherein only one end face 5 can be seen.

The cooling channels 4 are introduced by a Bohroperation in the pipe wall 2, and that before the mold tube 1 is bent. By bending the cooling channels 4 can then partially deform so oval that the inner contour 3 towards larger surface areas are formed, whereby the heat dissipation is improved.

The specific inner contour 3 of the mold tube 1 has rounded transitions 6 between a flange region 7 on the one hand and a wall region 9 delimiting a web region 8 on the other hand. The distance A between two cooling passages 4 adjacent to one another in the transitions 6 is smaller than the distance B in the remaining wall sections 9.

While in the embodiments of Figures 1 and 2, the cooling channels 4, the Kokillenrohre 1 enforce over its entire length L, it is also conceivable that provided in the transitions 6 cooling channels 4 from the upper end face 5 of the pipe wall 2 to about the middle height range the pipe wall 2 extend. These cooling channels 4 can be connected to one another to form a cooling circuit at their upper end sides and fed via Kühlmediumzuführungen and Kühlmediumabführungen in the middle height range of the pipe wall 2 with a cooling medium.

In addition, the mold tube 1 may be embedded in a matched to the outer contour 10 of the pipe wall 2 Wasserleitmantel, so that the mold tube 1 is surrounded in total by a flow-through with a cooling medium cooling gap.

FIG. 3 shows, in a somewhat different perspective, another embodiment of a mold tube 11 with an inner contour 12 in the beam blank format, likewise with rounded transitions 13 between, on the one hand, a flange region 14 and, on the other hand, a web region 15 delimiting wall sections 16 Embodiment cooling holes 4 are present only in the transition areas 13. The entire mold tube 11 is embedded in a manner not shown in a matched to the outer contour 17 of the tube wall 18 Wasserleitmantel over which both the remaining wall portions 16 and provided with cooling holes 4 transition areas 13 are cooled.

REFERENCE NUMBERS

1 -

Mold pipe

2 -

Pipe wall v. 1

3 -

Inner contour v. 1

4 -

cooling channels

5 -

End faces v. 2

6 -

Transitions between 7 and 8th

7 -

flange

8th -

web region

9 -

wall sections

10 -

Outer contour v. 1

11 -

Mold pipe

12 -

Inner contour v. 11

13 -

Transitions between 14 u. 15

14 -

flange

15 -

web region

16 -

Wall section v. 18

17 -

Outer contour of 18

18 -

pipe wall

A -

distance

B -

distance

D -

Thickness v. 2

L -

Length v. 1

KW -

cooling water

Claims (8)

1. Mould pipe for the continuous casting of metals, the pipe wall (2) of which has an inner contour (3) in the beam blank format with rounded transitions (6) between wall sections (9) bordering, on the one hand, a flange region (7) and, on the other hand, a web region (8), wherein the inner contour (3) can be cooled indirectly by an externally supplied cooling medium (KW), and wherein provided in the pipe wall (2) are cooling channels (4) extending in its longitudinal direction, characterised in that the spacing (A) between two cooling channels (4) adjacent to one another in the transitions (6) is smaller than the spacing (B) in the remaining wall sections (9).
2. Mould pipe for the continuous casting of metals, the pipe wall (18) of which has an inner contour (12) in the beam blank format with rounded transitions (13) between wall sections (16) bordering, on the one hand, a flange region (14) and, on the other hand, a web region (15), wherein the inner contour (12) can be indirectly cooled by an externally supplied cooling medium (KW) and wherein provided in the pipe wall (18) are cooling channels (4) extending in its longitudinal direction, characterised in that the cooling channels (4) are only provided in the rounded transitions (13) and the remaining wall sections (16) and the rounded transitions (13) can be cooled by a water guiding jacket adapted to the outer contour (17) of the pipe wall (18).
3. Mould pipe according to claim 1, characterised in that a water guiding jacket adapted to the outer contour (10) of the pipe wall (2) is provided.
4. Mould pipe according to any one of claims 1 to 3, characterised in that the cooling channels (4) provided in the transitions (6, 13) extend from the upper end face (5) of the pipe wall (2, 18) to approximately the middle height region of the pipe wall (2, 18).
5. Mould pipe according to any one of claims 1 to 4, characterised in that cooling medium supply lines and cooling medium discharge lines connected to the cooling channels (4) are provided in the outer contour (10, 16) of the pipe wall (2, 18).
6. Mould pipe according to claim 5, characterised in that the cooling medium supply lines and cooling medium discharge lines are provided in the middle height region of the pipe wall (2, 18).
7. Mould pipe according to any one of claims 2 to 6, characterised in that the cooling channels (4) have cooling medium (KW), which flows between the pipe wall (2, 18) and the water guiding jacket, flowing through them.
8. Mould pipe according to any one of claims 1 to 7, characterised in that it has a double T-shaped cross-section.

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