JPH0919751A - Continuous casting method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent a breakout in a continuous casting method. SOLUTION: In a continuous caster provided with a hydraulic cylinder system oscillation mechanism, cast slab friction force in a mold is measured with fluid pressre, and when the friction force is 1.5-2.0 times or more of that at the stationary time, the stroke of oscillation is made to large or the waveform of the oscillation is made to non-sine waveform by changing a mold ascending/ descending speed. By this method, since the friction force of the cast slab in the mold can accurately be measured, the breakout can be previously prevented without deteriorating the quality of the cast slab from happening.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a continuous casting method for preventing breakout in continuous casting of steel.

[0002]

2. Description of the Related Art In continuous casting of steel, in order to reduce friction between the mold and the slab, prevent seizure, and perform stable casting, the mold is moved up and down by attaching an oscillation device. The mold is vibrated and a lubricant such as mold powder or repseed oil is added to the mold. Depending on the type of this lubricant, mold vibration conditions and casting conditions, surface quality cracks, vertical corner cracks, lateral cracks, slag, etc. that occur on the surface of the slab will have a large adverse effect on the quality of the slab, so an appropriate selection should be made. Is necessary and management is important.

Further, the frictional force between the mold and the cast piece causes a serious problem in operation when not only the quality of the cast piece is deteriorated but also the breakout occurs due to the increase of the frictional force. FIG. 5 is an explanatory diagram showing a state of generation of a frictional force between the mold and the slab. That is, the solidified shell 2 in the mold 1 is pressed against the copper plate 1a of the mold 1 by the static iron pressure W of the molten steel 4 in the slab 3.
In this state, the slab 3 is pulled out downward. At that time, a sliding frictional resistance is generated between the solidified shell 2 and the copper plate 1a of the mold 1. In order to minimize this frictional force f,
The mold powder 5 is used, and a powder melting layer is formed between the solidified shell 2 and the copper plate 1a to lubricate the two.

Therefore, as described above, the quality of the cast slab 3 is greatly affected by the lubricating characteristics of the mold powder 5, and the pulling resistance is also increased or decreased.
Moreover, the solidified shell 2 in the mold 1 is broken, and the molten steel 4 and the copper plate 1 are broken.
When the sticking phenomenon 6 occurs with the a, the pull-out resistance force, that is, the frictional force f rapidly increases, and if the casting is continued as it is, the solidified shell 2 is broken and a breakout occurs. Therefore, conventionally, the lubrication characteristics of the mold powder 5 are grasped, the mold powder most suitable for the casting conditions is selected, and the fluctuation of the frictional resistance force f during casting is detected, and the fluctuation is equal to or more than a certain value. In that case, a method of preventing breakout is implemented by means such as reducing the casting speed.

Of the above-mentioned breakout prevention measures, the variation in the frictional resistance force f during casting is detected, and when the variation exceeds a certain value, the casting speed is reduced and the friction between the mold and the slab in the corresponding method is dealt with. A load cell method (see Japanese Utility Model Laid-Open No. 3-116249, etc.) or an acceleration sensor method is used to detect force. However, the load cell method or the acceleration sensor method has a low detection accuracy and may deteriorate the slab quality. Therefore, it is not effective as a breakout prevention measure.

On the other hand, CAMP-ISIJ VoL. 1
(1988) -181 to 184, "Estimation of limit drawing speed of continuous casting machine of fixed mold vibration type", means for accurately measuring frictional force between a mold wall and a cast piece is disclosed. . This measuring method measures the frictional force between the mold wall and the slab by measuring the pressure difference between the inlet side and the outlet side of the hydraulic cylinder of the mold oscillating device (oscillation device) driven by hydraulic pressure. Is the way. However, the technology described in the document relates to a means for grasping the limit of the casting speed by measuring the frictional force between the mold wall and the slab, and for the purpose of preventing breakout. Nor does the document disclose the prevention of breakouts based on frictional forces between the mold wall and the slab.

[0007]

SUMMARY OF THE INVENTION The present invention is a method for measuring the frictional force between a mold wall and a slab and preventing breakout from fluctuations in the frictional force, as described in the above-mentioned document. An attempt is made to propose a continuous casting method capable of effectively preventing breakout by using a means for accurately measuring a frictional force between a mold wall and a cast piece.

[0008]

The continuous casting method according to the present invention measures the frictional force of a slab in a mold, and when the frictional force is 1.5 to 2.0 times or more of the steady state, the oscillation of the oscillation is performed. It is characterized by increasing the stroke or setting the oscillation waveform condition to a non-sine waveform. Specifically, continuous casting is performed by a continuous casting machine equipped with a fluid pressure cylinder type oscillation mechanism. In the method, the slab friction force in the mold is measured by the fluid pressure, and when the friction force is 1.5 to 2.0 times or more of the steady state, the stroke of the oscillation is increased by the stroke varying mechanism of the fluid pressure cylinder. Alternatively, the mold ascending / descending speed is changed by controlling the fluid pressure supply amount to make the oscillation waveform a non-sine waveform.

In the present invention, the stroke of oscillation means the vertical vibration width of the mold, and the non-sine waveform (non-sine vibration waveform) means the vibration waveform of the mold. In continuous casting, as a mold vibration condition, the relative speed when the mold is raised is reduced and the vibration 1
By increasing the positive strip time within the cycle, it is possible to increase the powder consumption and reduce the liquid friction force. It is also necessary to apply compressive force to the initial solidified shell during the negative strip period. A mold vibration waveform satisfying such conditions, that is, a mold vibration waveform in which the mold ascending speed is slow and the descending speed is fast is called "non-sine waveform".

Further, in the present invention, the timing when changing the stroke of the oscillation or changing the mold ascending / descending speed to make the oscillation waveform a non-sine waveform is 1 when the slab friction force in the mold is steady. .5-2.
The reason why it is defined as 0 times or more is as follows.
That is, when the seizure or restraint of the slab occurs in the mold during casting, the frictional force of the slab inevitably increases, and actually increases to about 5 times that during normal casting. That is, when the frictional force of the slab is increased to about 5 times that during normal casting, breakout occurs. Therefore, to prevent breakouts,
It is necessary to take countermeasures before the occurrence of the problem. As the timing, in the present invention, when the frictional force of the cast slab in the mold is steady.
It was defined as 5 to 2.0 times or more. When the slab frictional force is less than 1.5 to 2.0 times the steady state, such an increase in the frictional force hardly causes breakout.

In the present invention, as described above, when the frictional force of the slab becomes 1.5 to 2.0 times or more that of the steady state, the frictional force of the slab is changed by changing the conditions of the oscillation (stroke, mold rising speed). To prevent breakout. In other words, by increasing the oscillation stroke, you can increase the powder consumption,
Partial restraint (sticking phenomenon) is avoided and a frictional force reduction effect is obtained, so that breakout can be prevented. Further, by changing the mold ascending speed to change the mold vibration waveform to a "non-sine waveform", the powder consumption amount can be increased and the liquid-solid friction force can be reduced, so that the breakout can be prevented. If the frictional force cannot be reduced by taking such an action, the casting speed is reduced to prevent breakout.

[0012]

1 is a schematic view showing the operating principle of an oscillation device driven by a hydraulic cylinder, FIG. 2 is a schematic view showing an example of a device configuration for carrying out the method of the present invention, and 10 is a hydraulic pressure. Cylinder, 11-1, 11-
2 is a lever, 12 is a frictional force measuring device, 13 is a hydraulic control system, and 14 is an alarm.

That is, in the case of a continuous casting machine equipped with an oscillation device driven by the hydraulic cylinder 10, the frictional force between the wall of the mold 1 and the slab 3 is at the inlet side of the hydraulic cylinder 10 of the oscillation device. It can be accurately determined by measuring the pressure P ₁ and the outlet pressure P ₂ . That is, in the case of the oscillation device driven by the hydraulic cylinder 10, since the fluctuation of the frictional force applied to the mold 1 appears as the fluctuation of the hydraulic pressure, the pressure fluctuation is constantly measured to accurately calculate the slab frictional force. It becomes possible to do.

The slab friction force can be calculated by the following equations (1) to (6). W ₁ = P ₁ × S ₁ (1) Formula W ₂ = P ₂ × S ₂ (2) Formula Wfc = W ₁ -W ₂ (during casting) (3) Formula Wfo = W ₁ -W ₂ ( Off-line) (4) Formula Wf = (Wfc-Wfo) × r (5) Formula Ef = Wf / [2 × (W + d) × Le] Formula (6) where Wf: Total friction force S: Hydraulic cylinder Cross-sectional area (cm ² ) r: Lever ratio (L ₁ / L ₂ ) W: Mold width (cm) d: Mold thickness (cm) Le: Mold effective length (cm) P ₁ : Hydraulic cylinder inlet hydraulic pressure (kg / cm ² ) P ₂ : Hydraulic pressure at hydraulic cylinder exit side (kg / cm ² ) Ef: Friction force between mold wall and slab (kg / cm ² )

Here, the fact that Wfc during casting becomes larger than Wfo during offline is due to the frictional force between the casting mold and the slab, and the breakout prevention according to the present invention increases the frictional force of Wfc. Is to detect.
Therefore, when the frictional force is increased, the breakout is prevented by changing the oscillation vibration condition (stroke, waveform, etc.) to reduce the frictional force.

That is, according to the present invention, when the frictional force between the mold and the slab is 1.5 to 2.0 times or more the steady state, the stroke varying mechanism of the fluid pressure cylinder 5 increases the oscillation stroke, or Breakout is prevented by changing the mold ascending / descending speed by controlling the fluid pressure supply amount and making the oscillation waveform a non-sine waveform.

Specifically, as shown in FIG. 2, the pressure P ₁ on the inlet side and the pressure P ₂ on the outlet side of the hydraulic cylinder 10 of the oscillation device are input to the friction force measuring device 12, and based on the values thereof. The pressure fluctuation is calculated according to the above formula, and the mold 1 is used.
The frictional force between the wall and the slab 3 is measured. Then, when the measured value (friction force) becomes 1.5 to 2.0 times or more that in the steady state, the alarm device 14 is activated and an alarm is issued at the same time.
An oscillation condition change command is sent to the hydraulic control system 13, and the stroke of the oscillation is increased by the variable stroke mechanism of the fluid pressure cylinder 10, or the mold ascending / descending speed is changed by controlling the fluid pressure supply amount to obtain the oscillation waveform. Is taken as a non-sine waveform.

Here, as the stroke varying mechanism of the fluid pressure cylinder 10, a mechanism for changing the supply pressure to the hydraulic cylinder 10 by the pressure control valve of the hydraulic control system 13 can be used. Further, the mold ascending / descending speed can be changed by changing the pump discharge amount of the hydraulic control system 13 or by adjusting the flow rate to the hydraulic cylinder 10 by a method of squeezing the oil with a flow rate adjusting valve.

[0019]

[Example] The size is 90 to 120 mm thick x 1000 mm
FIG. 3 shows a slab frictional force detection state in continuous casting of a slab by a continuous casting machine having a width mold and equipped with an oscillation device (hydraulic cylinder drive). That is, FIG.
Shows the pressure fluctuation on the outlet side of the hydraulic cylinder of the charge oscillating device where seizure and restraint occurred during casting and breakout occurred.
It can be seen that the increase in frictional force is markedly caused by the occurrence of seizure between the mold and the slab. FIG. 4 shows the result of conversion of the increase in frictional force into the average frictional force of cast slabs. That is, Fig. 4 shows the relationship between the casting speed and the frictional force for each steel type. When seizure or restraint occurs during casting, the slab frictional force is about 5 times that of normal casting (steady state). You can see that it has reached. In other words, when the slab friction force reaches about 5 times that during normal casting, breakout occurs.

Therefore, in order to prevent this breakout, the method of the present invention is applied to the above-mentioned slab continuous casting, and when the slab friction force becomes 1.5 times that in normal casting, the stroke of the hydraulic cylinder is changed. As a result of increasing the oscillation stroke from 6.0 mm at the time of normal casting to 8.0 mm by the mechanism, an increase in the frictional force of the slab was suppressed and seizure of the slab was prevented. Also, in the same continuous casting, when the slab friction force becomes 2.0 times that in normal casting, the fluid pressure supply amount to the hydraulic cylinder is controlled to control the mold ascending / descending speed from the sine wave during normal casting. When the oscillation waveform was changed to a non-sine waveform by changing to a non-sine wave, an increase in the frictional force of the slab was suppressed and seizure of the slab was prevented as in the above case.

[0021]

As described above, according to the method of the present invention, by changing the oscillation condition on the basis of the fluctuation of the slab friction force, the slab friction force is reached before the slab friction force reaches the solidified shell breaking stress. Since the one-sided frictional force can be reduced, breakout can be prevented in advance, which has a great effect on improving the quality of the slab and stabilizing the continuous casting.

[Brief description of the drawings]

FIG. 1 is a schematic diagram showing the operating principle of an oscillation device driven by a hydraulic cylinder.

FIG. 2 is a schematic diagram showing an example of a device configuration for carrying out the method of the present invention.

FIG. 3 is a diagram showing a variation state of a slab friction force in the example of the present invention.

FIG. 4 is a diagram showing a relationship between a casting slab average frictional force and a casting speed in the example of the present invention.

FIG. 5 is an explanatory diagram showing a state of generation of a frictional force between a continuous casting mold and a slab.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Mold 1a Copper plate 2 Solidification shell 3 Cast piece 4 Molten steel 5 Mold powder 6 Sticking phenomenon 10 Hydraulic cylinders 11-1 and 11-2 Lever 12 Friction force measuring device 13 Hydraulic control system 14 Alarm device

Claims (2)

[Claims] 1. A slab friction force in a mold is measured, and when the friction force is 1.5 to 2.0 times or more the steady state, the oscillation stroke is increased or the oscillation waveform condition is set. A continuous casting method characterized by a non-sine waveform. 2. A method of continuous casting using a continuous casting machine equipped with a fluid pressure cylinder type oscillation mechanism, wherein the slab friction force in the mold is measured by fluid pressure, and the friction force is 1.5 when the friction force is steady. When the stroke is up to 2.0 times or more, increase the oscillation stroke by the variable stroke mechanism of the fluid pressure cylinder, or change the mold lifting speed by controlling the fluid pressure supply amount to make the oscillation waveform non-sinusoidal. A continuous casting method characterized by: