EP0213060A2 - Process and withdrawal apparatus used in the horizontal continuous casting of metals, especially of steel - Google Patents

Abstract

In the horizontal continuous casting process, the cast strand is removed from the horizontal continuous casting mold by pulling. In order to control the flow of liquid melt as a function of the drawing stroke, which is also determined by the inertia of the mass of the molten metal, it is proposed that, in the case of a drawing stroke adjustable in the 0.1 mm range, the drawing movement in each case has a controllable acceleration phase, one on it subsequent phase of uniform speed and a phase of delay and that the cycle time is a minimum of 0.15 sec and a maximum of 1 sec.

Description

The invention relates to a method and a pull-out device for the horizontal continuous casting of metal, in particular steel, in which the cast strand is gradually pulled out and subsequently moved back, the drawing stroke being greater than the return stroke and wherein holding times of at least 0 in each case on a drawing stroke and a return stroke. 01 sec up to a maximum of 0.5 sec and pulling stroke and return stroke are generated hydraulically.

In the horizontal continuous casting process, the cast strand is removed from the horizontal continuous casting mold by pulling. With each drawing stroke, molten metal flows into the space released by the solidified casting section. The inflow of liquid melt as a function of the drawing stroke is determined by the inertia of the mass of the molten metal. A very rapid pulling of the cast strand therefore leads to the sluggish flow of the molten metal, whereby later cavities in the solidified cast strand cannot be avoided. It is therefore necessary to design the horizontal continuous casting process and the associated pull-out device in such a way that corresponding pulling strokes and pulling speeds are precisely observed in order to avoid the cavities mentioned.

The horizontal continuous casting process described at the outset is known from the F1 magazine RIQ (Rexroth Information Quarterly), June 1985, pages 32 and 33.

Adherence to the drawing strokes or drawing speeds by the pull-out device can, however, only be ensured if the clamping force of pairs of clamping jaws is adjusted at the same time, which grips the cast strand accordingly cheaply. A suitable clamping device allows the clamping force to be adjusted in order to be able to adapt it to the strand format and to be able to fully use the pulling force in the event of malfunctions in the casting operation.

The object of the invention is to adapt the drawing strokes and the clamping force in such a way that the cast strand is securely clamped and at the same time damage to the strand surface is reduced to a minimum. In addition, the dosing of the drawing path mentioned at the beginning is to be carried out in coordination with the drawing speed.

The stated object is achieved on the basis of the method mentioned at the outset in that, with a pulling stroke adjustable in the 0.1 mm range, the pulling movement in each case has a controllable acceleration phase, a subsequent phase of uniform speed and a phase of deceleration and that Cycle time is a minimum of 0.15 sec and a maximum of 1 sec. The parameters mentioned now allow the drawing path to be matched to the drawing speed, with the total cycle time being limited. At the same time, the clamping force is reduced to the required level and damage to the strand surface is reduced.

The pull-out device advantageously used to carry out the method according to the invention is based on at least one clamping device which can be moved in and against the strand running direction and which consists of pairs of clamping jaws which can be adjusted to the strand cross section by means of hydraulic piston-cylinder units.

The transmission of a reduced clamping force with a simultaneous reduction in the damage to the strand surface and in the parameters specified in terms of the method is achieved according to the further invention in that the pairs of clamping jaws are arranged vertically, that from one pair of clamping jaws at least one clamping jaw is controllable differently from the other for format changes and that the jaws of a pair of jaws are controlled simultaneously in the clamp-release operation. The vertical arrangement of the pairs of jaws basically enables the advantageous construction of space-saving multi-strand systems. In covering the functions, however, this arrangement is also advantageous for the format change. The upper jaw will therefore generally be able to be moved to considerably different heights, while the lower jaw can only be adjusted in height in the clamp-release operation.

According to the further invention, it is provided that the lower jaws and the upper jaws can each be actuated via separate piston-cylinder drives. The invention follows the division into independent piston-cylinder drives with different strokes.

It is also advantageous that the lower jaws can be adjusted against a fixed stop by means of a piston-cylinder unit. Such a stop can easily be aligned with the horizontal continuous casting mold, so that the cast strand always remains in a reference plane.

The design of a multi-line system and thus the solution to the space problem is supported by the fact that the piston-cylinder drives for the respective clamping jaws run parallel with their longitudinal axes. Such an arrangement can e.g. done vertically.

The control of the piston-cylinder drives is also favored by the fact that the opening path of the clamping jaws is limited by means of a displacement sensor arranged inside the respective piston-cylinder drive.

As a further improvement, it is provided that the clamping device can be moved with the clamping jaws on a path whose length corresponds to at least three pulling strokes. Therefore takes place per drawing stroke one clamping of a pair of jaws and either a pull stroke of the other pair of jaws or an empty return stroke of the other pair of jaws.

A particularly advantageous movement of the clamping device is designed in such a way that two movable pairs of jaws are provided, one pair of jaws taking over the strand from the other pair of jaws for the duration of at least three pulling strokes.

• Fig. 1 ein Bewegungsdiagramm für einen Ziehhub,
• Fig. 2 eine Ansicht der Auszieheinrichtung in Richtung des Gußstranges und
• Fig. 3 eine Seitenansicht der Auszieheinrichtung gemäß Fig. 2, (in kleinerem Maßstab gezeichnet).

An embodiment of the invention is shown in the drawing and will be described in more detail below. Show it:

• 1 is a movement diagram for a drawing stroke,
• Fig. 2 is a view of the puller in the direction of the cast strand and
• Fig. 3 is a side view of the extractor of FIG. 2, (drawn on a smaller scale).

According to FIG. 1, the time t in milliseconds is plotted on the abscissa in a coordinate system and the pulling speed V in meters / min on the ordinate. The movement curve 1 represents a complete cycle 2 of a drawing stroke with recoil and holding time.

The pulling stroke movement is divided into a controllable acceleration phase 3, the control e.g. is formed by two different acceleration zones 3a and 3b. This is followed by a phase 4 of uniform drawing speed and a delay phase 5. When passing through the abscissa (speed = zero), a recoil 6 is initiated, which reaches point 7. From a point 8, the braking of the recoil (curve part 9) is initiated. This is followed by a stopping time 10 until the start of the new cycle with the acceleration zone 3a.

The pull-out device according to FIGS. 2 and 3 has two slides 11, each of which is assigned a clamping device 12, the clamping device consisting of a pair of clamping jaws with clamping jaws 13a and 13b.

The carriage 11 are actuated by a control, not shown, which is assigned to two drives.

The clamping device 12 has a support frame 14 with legs 14a and 14b, an upper yoke 14c and a lower yoke 14d. A first piston-cylinder unit 15 is mounted on the upper yoke 14c and is each articulated with its piston rod 15a on the clamping jaws 13a.

In the area of the lower yoke 14d and about a pivot axis running in the direction of the central strand axis 16a, an angle lever 18 is rotatably mounted, which is located next to the cast strand 16 with its angled leg 18a. The angle lever 18 forms a stop with the angle corner 18b at the same time, so the clamping jaw 13b, which is connected to the angle lever 18, is guided into the plane described, in which the underside of the cast strand 16 and the underlying inner wall of the (not shown) ) Horizontal continuous casting mold lies.

A second piston-cylinder unit 19 is articulated to a bearing eye 18d on the leg 18a. For the opposite bearing 20 there is a corresponding bearing eye 14e on the lower yoke 14d.

For a multi-strand caster, it is advantageous to arrange the piston-cylinder units 15 and 19 with their longitudinal axes 15b and 19a in parallel in order to save space. Within the piston-cylinder units 15, 19 there is a displacement sensor, not shown, which works as an inductive displacement transducer and detects the actual position. The setpoint for the movement of the clamping jaws 13a, 13b is controlled by a microprocessor.

The clamping device 12 with the clamping jaws 13a, 13b can be moved in a way which practically corresponds to three drawing strokes (FIGS. 1 and 3). Two movable pairs of jaws 13a, 13b (FIG. 3) alternately take over the cast strand 16, with one pair of jaws taking over the cast strand 16 from the other for the duration of a third drawing stroke.

Claims (8)

1. Method for the horizontal continuous casting of metal, in particular steel, in which the cast strand is gradually withdrawn and subsequently moved back, the drawing stroke being greater than the return stroke and wherein holding times of at least 0.01 seconds to a maximum of 0 for a drawing stroke and a return stroke , 5 sec and pulling stroke and return stroke are generated hydraulically,
characterized,
that with a pull stroke adjustable in the 0.1 mm range, the pulling movement each has a controllable acceleration phase, a subsequent phase of uniform speed and a phase of deceleration and that the cycle time is a minimum of 0.15 sec and a maximum of 1 sec . 2. Extracting device for carrying out the method according to claim 1, with at least one clamping device which can be moved in and against the strand running direction and which consists of clamping jaw pairs which can be adjusted to the strand cross section by means of hydraulic piston-cylinder units,
characterized,
that the pairs of jaws (13a, 13b) are arranged vertically, that of a pair of jaws (13a, 13b) at least one jaw (13a or 13b) can be controlled differently in relation to the other for format changes, and that the jaws of a pair of jaws (13a, 13b) in Clamp-release operation are controlled simultaneously. 3. pull-out device according to claim 2,
characterized,
that the lower jaws (13b) and the upper jaws (13a) can each be actuated via separate piston-cylinder drives (19, 15). 4. pull-out device according to claims 2 and 3,
characterized,
that the lower jaw (13b) can be adjusted against a fixed stop by means of its piston-cylinder unit (19). 5. pull-out device according to claims 2 to 4,
characterized,
that the piston-cylinder drives (15, 19) for the respective clamping jaws (13a, 13b) run parallel with their longitudinal axes (15b, 19a). 6. pull-out device according to claims 2 to 5,
characterized,
that the opening path of the clamping jaws (13a, 13b) is limited by means of a displacement sensor arranged inside the respective piston-cylinder drive (15, 19). 7. pull-out device according to claims 2 to 6,
characterized,
that the clamping device (12) with the clamping jaws (13a, 13b) is movable on a path (21), the length of which corresponds to at least three pulling strokes. 8. pull-out device according to claim 7,
characterized,
that two movable pairs of jaws (13a, 13b) are provided, one pair of jaws (13a, 13b) taking over the casting (16) from the other pair of jaws (13a, 13b) for the duration of at least three pulling strokes.

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