The invention relates to a dummy bar for a continuous casting installation for casting a metal strand and having a dummy bar head, a transition piece, and a link chain, wherein the transition piece is arranged between the dummy bar head and the link chain, wherein the transition piece and/or the link chain are formed of a plurality of links connected with each other in an articulated manner, and wherein the links are pivotable relative to each other about a transverse axis extending perpendicular to a longitudinal axis of the dummy bar. The invention further relates to a method of continuous casting a metal strand with which such a dummy bar is used.
A dummy bar of the type described above is used for starting a continuous casting process in a continuous casting installation. The mold of the continuous casting installation is closed at its outlet with the dummy bar head in order to be able to introduce melt into the mold in a first complete process; the dummy bar head prevents an immediate exit of the melt from the mold. After a first solidification, the formed strand is withdrawn from the mold, together with the dummy bar, and is transported over the strand guide of the continuous casting installation and a horizontal roller table. Subsequently, the dummy bar is again transported to the mold to be available for the next starting process. At so-called “top feeding,” the dummy bar is displaced in a loop through the continuous casting installation, i.e., behind a horizontal roller table, it is displaced upwardly to a level of the casting platform and is pulled onto a dummy bar rack and is transported again in direction of the mold.
Dummy bars of the above-described type are disclosed, e.g., in DE 2 103 417 A1, in EP 0 043 365 B1, in U.S. Pat. No. 4,632,175, and in DE 10 2006 023 503 B3.
Because the dummy bar head, as a rule, has a greater thickness than the following link chain, when the dummy bar rests flatly, e.g., on the dummy bar rack, from time to time, increased stresses are generated in the articulated joints; the link-shaped dummy bar buckles up. Therefore, the links or the articulated joints are subjected to an increased load which causes wear, in particular, when the dummy bar head together with the transition links lies on the dummy bar rack. This is particularly the case when at a relative pivotal movement, the articulated joints do not allow any evasion of the colliding chain links. In the stand-by and exchange position, the handling of the dummy bar is problematic, in particular when sections of the dummy bar need be replaced.
To this end, it is mostly necessary to lift the dummy bar with a crane in order to reduce the stresses in the articulated joints.
The object of the present invention is to modify a dummy bar of the above-mentioned type so that without special means, it would be possible to prevent stresses in the articulated joints of the dummy bar when it rests flatly, in particular, on a dummy bar rack. Further, a method of its use is suggested.
The solution for achieving this object is characterized, according to the invention, in that at least one articulated joint between two links connected with each other in articulated manner is so formed that it provides for a relative movement of the links about the transverse axis which is greater than any pivot angle encountered during the use of the dummy bar, wherein a locking element, which is displaceable in a direction perpendicular to the longitudinal axis of the dummy bar and perpendicular to the transverse axis, is arranged in or on the articulated joint, and wherein the locking element can occupy a position in which a pivotal movement of the links is not influenced by the locking element, and can occupy a position in which the pivotal movement of the links in a pivotal direction is limited to a predetermined pivot angle.
The locking element is advantageously displaceably arranged in a linear guide.
Advantageously, the locking element assumes its position exclusively under action of the gravity force.
The articulated joint provided with a locking element can be arranged only in the transition piece of the dummy bar.
Mostly, a thickness of the dummy bar head is greater than a thickness of the link chain.
The method of continuous casting a metal strand in which a dummy bar of the described type is used, contemplates that, firstly, the dummy bar is introduced in a mold from above, then that the dummy bar is displaced from the mold downwardly along a strand guide, that the dummy bar is transported behind the strand guide on a horizontal roller table, that the dummy bar is pulled from the roller table with the dummy bar head being automatically disconnected from the hot strand that the dummy bar is displaced only horizontally in direction of the mold and, finally, the dummy bar is again introduced from above into the mold for a next cast. Thus, “top feeding” is provided. According to the invention, the method is characterized in that the locking element occupies, during introduction in the mold, the position in which the locking element does not influence the pivotal movement of the links.
It is further provided that the locking element is displaced, during movement of the dummy bar downwardly along the strand guide, from the position in which the locking element does not influence the pivotal movement of the links into the position in which the pivotal movement of the links is limited to a predetermined angle.
It further can be provided that the locking element occupies, during displacement of the dummy bar on the horizontal roller table, the position in which the pivotal movement of the links is limited to a predetermined angle.
Further, the locking element can displace, during the movement of the dummy bar upwardly onto the dummy bar rack, from the position in which the pivotal movement of the links is limited to a predetermined angle, into position in which the locking element does not influence the pivotal movement of links.
Finally, it can be provided that the locking element occupies, during the horizontal movement of the dummy bar on the casting platform toward the mold, the position in which the locking element does not influence the pivotal movement of the links.
The displacement of the locking element between its positions takes place here advantageously exclusively under the action of the gravity force of the locking element.
With the chain links being supported, in the horizontal position of the roller table, beneath each other, the vertically movable support disc displaces, as a result of the gravity force, in a corresponding slot, in accordance with the use status of the dummy bar, i.e., dependent on the actual location and the position of the dummy bar. The support disc, which functions as a locking element, either allows deviations of two adjacent chain links or prevents those, dependent on the position of the locking element in the articulated joint.
The proposed solution enables operation of the dummy bar with a very small wear and permits to achieve improved exchange conditions, independent of thickness ratios (ratio of the thickness of the dummy bar head to the thickness of the chain link). The dummy bar, as a result, does not form, even when laying flatly, any “hunchback” that, with existing solutions, leads to high stresses in the articulated joints.
The proposed method of use of such a dummy bar provides for “top feeding” and, thereby, for circulation of the dummy bar during its use, i.e., its use in a circulating system.
Thereby, the load of the chain links is substantially reduced, which also correspondingly reduces wear.
At the location of the locking members, transition pieces and the dummy bar head can be replaced, i.e., both functions are available at the separation point.
The drawings show an embodiment of the invention. In the drawings:
The dummy bar head 2 has a thickness D that is greater than a thickness d of the link chain 4.
As it is shown for the region of the transition piece 3, an articulated joint 7 supports two adjacent links 5, 6 for pivotal movement relative to each other about a transverse axis Q (pivot angle α, see
Of importance is, being taken into consideration later, axis T for a translational displacement and which extends perpendicular to both the longitudinal axis L and the transverse axis Q.
In
At a first side I, the dummy bar 1 is inserted in a mold 10.
At a second site II, behind the mold 10, the dummy bar 10 is displaced along a strand guide 11.
At a third side III, the dummy bar 1 is displaced in the strand guide and horizontally on a roller table 12, resting thereon.
At a fourth site IV, the dummy bar 1 is lifted, with a lever, not shown, upward to a level of a casting platform and is pulled onto a dummy bar rack 13.
At a site V, the dummy bar 1, which is located on the dummy bar rack 13, is finally displaced again in direction of the mold 10 to be available for next insertion. On the dummy bar rack 13, at the site V, if needed, exchange of portions of the dummy bar 1 can be carried out to adapt it, e.g., to another geometry of a mold.
In
a through 3h show enlarged sections of the links 5, 6, together with the articulated joint 7, corresponding to the sites I-V according to
To this end, the link 5 has a linear guide 9 extending in direction T, i.e., perpendicular to the transverse axis Q and to the longitudinal axis L. In the linear guide, a locking element 8 is located.
The locking element 8 is movable between two positions A and B:
In the position A (see, e.g.,
In another position B (see, e.g.,
The locking element 8 is displaceable under its own weight in a respective end region of the linear guide 9, i.e., in a locking or release position A, B.
As can be seen in
Number | Date | Country | Kind |
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10 2008 016 759.2 | Apr 2008 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2009/002035 | 3/19/2009 | WO | 00 | 12/7/2010 |