EP1029616A1 - Device for oscillating a continuous-casting mould - Google Patents

Abstract

A continuous casting mould oscillation mechanism comprises articulated lifting table guide rods (9) with articulation axes parallel to hydraulic lifting assembly articulations (6, 7). Continuous casting mould oscillation mechanism comprises two individual lifting tables (2) which support the mould (1) and which are articulated to the upper parts (6) of hydraulic assemblies (4, 4'), the lower parts of which are articulated to a stationary base frame (3). The lifting tables (2) are guided on the base frame (3) by articulated guide rods (9), the axes of the guide rod articulations (8, 8') being parallel to the hydraulic assembly articulations (6, 7).

Description

The invention relates to a device for oscillating a continuous casting mold, in particular for the continuous casting of thin slabs of steel, comprising a oscillating continuous casting mold, the oscillation drive with at a fixed Base frame arranged hydraulic units is formed.

In continuous casting, the mold is set in a periodic oscillation movement, to reduce the friction through a relative movement between the strand and the mold between the mold and the strand. This will make an undesirably high Friction of the strand on the mold wall is reduced. Furthermore, on the bathroom surface Granular to powdery casting powder in the mold after melting pulled into the gap between the mold and the strand as a lubricant.

With vertically reciprocating movements in the casting direction or in the opposite direction are the stroke and frequency of the oscillation in accordance with the casting speed adjustable parameters.

During an oscillation cycle, the mold changes as the glides past Strand the type of friction:

With the mold leading speed relative to the strand, the negative strip, and after reversing the direction to the positive strip, sliding friction is present. During sliding friction, tensile and compressive stresses are alternately transferred from the mold to the strand shell.
At approximately the same speed between the mold and the strand, in the direction reversal from negative strip to positive strip, there is static friction at which the resulting tensile and compressive stresses almost equalize. When the relative mold speed is increased or decreased, the mold breaks free of the strand. This leads to compression and thus to an increase in the speed of the strand shell when the mold is on its way down, and conversely to an expansion and thus to a reduction in speed of the strand shell when the mold is on its way up.

The alternating upsetting or stretching process of the strand shell causes in particular with a sinusoidal oscillation an oscillating excitation of the whole Strand. If this is in an unfavorable, for example harmonious Frequency range, it may. a. for swinging up the casting mirror in the mold come. Such a disadvantageous operating state can be particularly avoid by a non-sinusoidal movement of the mold, whereby a periodic bath level fluctuation is successfully dampened becomes.

Hydraulic oscillation drives for lifting tables are state of the art known from continuous casting equipment, the mold oscillation with any Allow speed curves, for example corresponding to an asymmetrical one Sinusoid. The positive and negative strip time can be divided into optimal areas, which is beneficial on the oscillation marks, their depth and shape affects and an improvement of the Surface quality causes.

For example, document DE 37 04 793 C2 describes a mold lifting device with two on a lifting table for the continuous casting mold, or directly on this articulated, rotatably drivable eccentric shaft. Between rotary drive and the eccentric shafts, at least one drive shaft is used, in which the joint head facing away from the eccentric shaft is arranged such that it can be changed in position and the rod ends are rotatable against each other. A non-sinusoidal motion sequence the mold is used in this device through conscious use of a gimbal error that occurs when a propeller shaft is not is used in alignment between the waves. By changing height and lateral displacement of the rotary drive are different, non-sinusoidal Movements of the mold can be realized.

Document EP 0 121 622 B1 describes a continuous caster using a mold mounted in a frame, which is controlled by an electro-hydraulic Servo device is vibrated. The generation of vibrations is preselected according to one generated by a function generator Vibration ampute signal operated at a frequency higher than that Natural frequency of the vibration device is.

The as yet unpublished patent application 198 17 701.1 discloses a device for continuous casting of steel, consisting of an oscillating in the casting direction, continuous casting mold held in a lifting table and at least one oscillating drive acting on the lifting table. The lift table is below his Formed table-level guide blocks, between which a stationary clamping block is arranged. Along the mold narrow sides are below the table level on both sides of the clamping block between or in this and the guide block adjacent to it at a distance from one another at least two individual, resiliently soft leaf springs in each other and in Reference to the respective arranged on the opposite side of the mold Leaf springs clamped in parallel position. The oscillation drive exists consisting of four hydraulic cylinders, two of which are arranged on each mold side and with one end on the guide blocks and the other End are attached to a stationary support frame.

An oscillation device described in document EP 0 732 978 B1 uses two clamped clamps on each side of the mold Leaf spring packages. Here, a hydraulic cylinder is arranged centrally under the mold on each side. With this solution, the lifting table was dispensed with - it became the Chill mold stored directly on the leaf springs.

The disadvantage of a guide with clamped leaf springs is the limitation of Lifting height, the absorption of only limited forces in the transverse direction of the leaf springs and the spring stiffness of the guide spring, which changes at non-sinusoidal mold speeds has a negative impact on leadership.

Starting from the aforementioned prior art, the object of the invention based on further improving known oscillation drives, and in particular a uncomplicated and compact device for decoupling the linear Relationship between casting speed and the oscillation parameters Stroke / frequency to specify, in particular an undesirable influence avoids the speed curve by a guide with spring characteristics and any setting of the ratio of stroke and frequency in one Realized device of the lowest possible height.

The object is achieved in a device mentioned in the preamble of claim 1 Kind with the features of the characterizing part of claim 1 solved. Inventive designs of the design principle used are specified in the subclaims.

Figur 1

eine Vorrichtung zum Oszillieren einer Stranggießkokille in Seitenansicht,

Figur 2

die Vorrichtung gemäß Fig. 1 in Draufsicht,

Figur 3

die Vorrichtung in Frontansicht.

Further details, features and advantages of the invention result from the following explanation of an exemplary embodiment shown schematically in the drawings. Show it:

Figure 1

a device for oscillating a continuous casting mold in side view,

Figure 2

1 in top view,

Figure 3

the device in front view.

The device shown in FIGS. 1 and 2 for oscillating a continuous casting mold 1, in particular for the continuous casting of thin slabs of steel, comprising the continuous casting mold 1 which can be oscillated in the casting directions or opposite direction and is arranged on two individual lifting table units, has an oscillation drive with two in total four hydraulic units 4, 4 'arranged on a stationary base frame 3 by means of joints 7, 7'.
Each lifting table 2 is articulated to the upper part of the hydraulic unit 4, 4 ', and its lower end is articulated to the base frame 3. Each lifting table 2 is from to levels xx; x'-x 'parallel planes between base frame 3 and lifting table 2 in the horizontal position articulated links 9.9' out. The axes of the joints 6,6 'and 7,7' on the hydraulic units 4,4 ', as well as the joints 8,8' on the links 9,9 'are at levels xx; x'-x 'aligned vertically.

The device described enables in a particularly uncomplicated and compact construction a decoupling of the linear relationship between Casting speed and the oscillation parameter stroke / frequency. In particular is through the arrangement of a vibration-neutral guidance by the handlebars 9,9 'avoided an undesirable influence on the speed curves and realizes any setting of the ratios of stroke and frequency. The device is free from resonance frequencies and has good guiding properties in all levels.

Lateral tilting of the device is prevented by the handlebars 9, 9 'have torsionally stiff and high transverse stiffness steel profiles.

As can be seen from FIGS. 2 and 3, the links 9, 9 'are arranged on the narrow sides 10, 10' of the mold 1.
In an alternative embodiment of the device it can be provided, for example, that the guidance of the lifting tables 2 is designed with a double-link arrangement.

An essential feature of the claimed device is that the Hydraulic units 4,4 'in parallel to the narrow sides 10,10' of the mold 1 Levels are arranged laterally at a distance from the lifting table 2 and that the Hydraulic units 4,4 'are double-acting servo cylinders.

The perspective front view of the device in Figure 3 shows the arrangement two individual lifting tables on the right and left under the mold 1, which are comparatively train small and compact units. In the resulting In between there is an optimal accessibility to the individual Construction elements 3 to 9. This advantageously allows quick access to these elements for installation and / or removal z. B. for maintenance work or check the water connections of the mold cooling or at Place the device on the base frame 3.

LIST OF REFERENCE NUMBERS

1.

continuous casting

Second

Lift table

Third

base frame

4th

hydraulic power unit

5th

boom

6th

Joint above

7th

Hinge below

8th.

joint

9th

handlebars

10th

narrow side

Claims (6)

Device for oscillating a continuous casting mold (1), in particular for the continuous casting of thin slabs of steel, comprising an oscillating continuous casting mold (1), the oscillation drive of which is designed with hydraulic units (4,4 ') arranged on a fixed base frame (3),
characterized by that the continuous casting mold (1) is arranged on two individual lifting tables, that the lifting table (2) is articulated to the upper part (6) of each hydraulic unit (4,4 '), and the lower part is articulated to the base frame (3), that the lifting table (2) with the base frame (3) by means of articulated links (9,9 ') is guided, and that the axes of the joints (6,6 ') and the joints (7,7') on the hydraulic units (4,4 '), and the axes of the joints (8,8') on the links (9,9 ') are aligned parallel to each other. Device according to claim 1,
characterized by
that the handlebars (9, 9 ') have torsionally stiff and high transverse stiffness steel profiles. Device according to claim 1 or 2,
characterized by
that the handlebars (9, 9 ') are arranged under the narrow sides (10, 10') of the mold (1). Device according to one or more of claims 1 to 3,
characterized by
that the guide of the lifting tables (2) is designed with a double handlebar arrangement. Device according to one or more of claims 1 to 4,
characterized by
that four hydraulic units (4, 4 ') are arranged in planes (x - x; x' - x ') parallel to the narrow sides (10, 10') of the mold (1) under the lifting table (2). Device according to one or more of claims 1 to 5,
characterized by
that the hydraulic units (4,4 ') are double-acting servo cylinders.

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