KR20120044433A - Apparatus for reducting nonunifrom flow of molten steel in the mold and method therefor - Google Patents

Abstract

PURPOSE: A device and a method for reducing drift current of molten steel in a mold are provided to improve the quality of molten steel by blocking the inflow of mold powder and air bubbles. CONSTITUTION: A device for reducing drift current of molten steel in a mold comprises an electromagnetic coil(20), a temperature sensor(30), and a control unit(40). The electromagnetic coil is installed on the right and left outer wall of a mold in the longitudinal direction of the mold and controls the acceleration and deceleration of molten steel discharge from a nozzle(1) to the mold. The temperature sensor is installed on the right and left sides of the mold. The control unit controls the electromagnetic coil to apply an electromagnetic field to the molten steel discharged from the nozzle according to the temperatures sensed by the temperature sensor.

Description

Molten steel flow drift reduction device in mold and reduction method using same {APPARATUS FOR REDUCTING NONUNIFROM FLOW OF MOLTEN STEEL IN THE MOLD AND METHOD THEREFOR}

The present invention is to control the flow rate of the molten steel in the mold by controlling the discharge rate of the molten steel flowing in the left and right through the temperature sensor and the electromagnetic coil installed on the outer wall surface of the left and right short sides of the mold to stabilize the flow of the molten steel, The present invention relates to an apparatus for reducing molten steel flow drift in a mold and a method for reducing the drift due to flow.

In general, a continuous casting machine is a facility for producing cast steel of a certain size by receiving a molten steel produced in a steelmaking furnace and transferred to a ladle (Tundish) and then supplied to a continuous casting machine mold.

The continuous casting machine includes a ladle for storing molten steel, a continuous casting machine mold for cooling the tundish and the molten steel discharged from the tundish into a strand having a predetermined shape, and a strand formed from the mold connected to the mold. It includes a plurality of pinch rolls to move.

In other words, the molten steel tapping out of the ladle and the tundish is formed of a strand having a predetermined width, thickness, and shape in a mold and is transferred through a pinch roll, and the strand transferred through the pinch roll is cut by a cutter to have a predetermined shape. It is made of a slab (Slab) or a slab (Bloom), billet (Billet) and the like.

An object of the present invention is to adjust the flow rate of the molten steel in the mold by controlling the discharge rate of the molten steel flowing in the left and right directions through the temperature sensor and the electromagnetic coil installed on the outer wall surface of the left and right short sides of the mold to stabilize the flow of the molten steel And, it is to provide a molten steel flow drift reduction device and a reduction method using the same to improve the quality of the molten steel, thereby to reduce the drift caused by the flow.

In order to achieve the above object, the molten steel flow drift reducing device according to the present invention comprises: an electromagnetic coil installed on the outer wall surface in the longitudinal direction of the mold; A temperature sensor installed at left and right short sides of the mold; And a control unit which controls an electromagnetic coil on the left and right sides of the mold outer wall surface according to the temperature of the mold short side portion detected by the temperature sensor and applies an electromagnetic field to the molten steel discharged from the nozzle.

Reduction method using the molten steel flow drift reduction device in the mold according to the present invention for achieving the above object, the short side through the temperature sensor is installed on each of the left and right short sides of the mold is heated in accordance with the flow phenomenon of the molten steel injected into the mold Measuring a negative temperature; Applying an electromagnetic field to molten steel discharged from the nozzle by controlling electromagnetic coils on the left and right sides of the mold outer wall according to the temperature measured by the temperature sensor; And changing a current value applied to the left and right short side electromagnetic coils of the mold in steps until the temperature of the electromagnetic field applied in the step of applying the electromagnetic field is close to the temperature of the left and right short side portions of the mold within a predetermined temperature difference. Characterized in that.

According to the molten steel flow drift reduction device and the reduction method using the same according to the present invention configured as described above, the molten steel is injected into the mold by measuring the short side temperature of the mold to apply the electromagnetic field applied to the left and right directions, respectively There is an advantage that can easily adjust the flow rate change of.

In addition, the surface of the molten steel is stabilized to block the inflow of mold powder and bubbles to improve the quality of the molten steel, and the flow in the mold is also stabilized to prevent operation accidents, there is an advantage in ensuring continuous operation.

1 is a view showing a drift reduction device according to an embodiment of the present invention.
2 is a perspective view showing a mold and an electromagnetic coil according to an embodiment of the present invention.
3 is a flow chart showing a method of reducing flow drift of molten steel according to an embodiment of the present invention.
Figure 4 is a graph showing the measurement of the temperature of the mold short side portion according to an embodiment of the present invention.
5 is a graph showing a current applied to the electromagnetic coil according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention. Like elements in the figures are denoted by the same reference numerals wherever possible. In addition, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

1 is a view showing a drift reduction device according to an embodiment of the present invention.

Referring to FIG. 1, the present invention includes an electromagnetic coil 20, a temperature sensor 30, and a controller 40 to control a flow rate of molten steel 2 discharged from a tundish.

The electromagnetic coil 20 is installed on the front, rear, left, and right outer wall surfaces of the mold 10 to adjust the flow rate of the molten steel 2 injected into the mold 10.

The temperature sensor 30 is installed on the left and right short sides of the mold 10 to measure the temperature of the short sides of the mold 10, respectively.

The temperature sensor 30 may be provided with one or a plurality of left and right short sides of the mold 10 to measure the temperature of the left and right short sides of the mold 10.

The control unit 40 controls the electromagnetic coil 20 on the left and right sides installed on the outer wall surface of the mold 10 according to the temperature of the short side of the mold 10 detected by the temperature sensor 30 to control the nozzle 1 from the nozzle 1. An electromagnetic field is applied to the molten steel 2 discharged.

In this case, the control unit changes the current mode applied to the left and right electromagnetic coils when the temperature deviation of the left and right short sides of the mold detected by the temperature sensors is greater than or equal to the reference value.

At this time, the current mode is composed of an EMLS (Electromagnetic Level Stabilizer) mode for reducing the flow rate of the molten steel (2) and an Electromagnetic Level Accelerator (EMLA) mode for increasing the flow rate of the molten steel (2).

That is, in more detail, the molten steel discharged from the nozzle 1 of the tundish flows in both sides of the mold 10 in the longitudinal direction.

Due to this flow, both side short sides of the mold 10 are heated. At this time, the discharge speed of the molten steel of the left and right both holes may be changed due to a fixation that may be formed in the hole formed in the nozzle 1.

As a result, the left and right short sides of the mold have different temperatures. The temperature of each of the short sides is measured by a temperature sensor and transmitted to the controller.

Electromagnetic Level Stabilizer (EMLS) to the left and right electromagnetic coil 20 according to the temperature in the electromagnetic coil 20 installed on the left and right outer wall surface of the mold 10 in the control unit 40 through the temperature transmitted from the temperature sensor 30 The flow rate of the molten steel 2 is controlled by applying a mode and an EMLA (Electromagnetic Level Accelerator) mode, respectively.

The flow drift reduction method using the above configuration is made as follows.

3 is a flow chart showing a method of reducing flow drift of molten steel according to an embodiment of the present invention.

Referring to FIG. 3, the molten steel 2 inside the tundish is injected into the mold 10 through the nozzle, and is divided in the left and right directions of the mold 10 through the hole formed in the nozzle 1 of the tundish. To be injected.

At this time, the molten steel (2) is flowed to both sides of the left and right sides of the mold by the hole of the nozzle 1, the molten steel (2) injected into the mold 10 flows in the left and right and up and down directions.

The flow rate of the molten steel 2 flowing in this way may be changed by the deposits formed in the holes of the nozzle 1.

Then, the temperature of the short side portion is measured through the temperature sensors 30 respectively installed on the left and right short side portions of the mold 10 heated according to the flow phenomenon of the molten steel 2 injected into the mold 10 (S10).

The temperature sensor 30 is installed on the left and right short sides of the mold 10 to measure the temperature of the short sides of the mold, respectively.

At this time, if the temperature difference of the left and right short sides of the mold measured by the temperature sensor is less than ± 10 ℃ to apply the EMLS mode to the electromagnetic coil installed on the left and right outer wall surface of the mold to maintain the flow rate of the molten steel discharged at low speed .

Then, when the temperature difference between the left and right short side portions of the mold 10 differs by ± 10 ° C. or more, vortices due to drift are generated on the surface of the molten steel 2, and the liquid mold powder injected into the surface of the molten steel 2 is mixed. The problem of changing the quality of the molten steel (2) may occur.

Molten steel 2 discharged from the nozzle 1 by controlling the left and right electromagnetic coil 20 installed on the mold outer wall surface according to the temperature of the left and right short sides of the mold 10 measured by the temperature sensor 30 Apply an electromagnetic field to the (S20).

At this time, in the direction in which the short side temperature of the mold 10 is low, the electromagnetic coil 20 applies an EMLA (Electromagnetic Level Accelerator) to accelerate the molten steel 2 discharged at a low speed.

In addition, in the direction in which the short side temperature of the mold 10 is high, an electromagnetic level stabilizer (EMLS) is applied from the electromagnetic coil 20 to reduce the molten steel 2 discharged at high speed.

When the temperature difference between the left and right short side portions of the mold 10 is ± 10 ° C. or more, the above process is performed. An electric field is applied to the outside of the mold 10 by applying a current corresponding to the EMLA mode. This increases the flow rate of the molten steel (2).

On the contrary, a current corresponding to an ELMS mode in the range of +15 to 25A is applied to the electromagnetic coil 20 having a high temperature at the short side of the mold 10 so that an electromagnetic field is applied to the inside of the mold 10. For this reason, the flow velocity of the molten steel 2 is lowered.

At this time, if the range of current applied to the electromagnetic coil 20 is lower than ± 15A, a voltage may be applied up to 500A, but the range may be small, thereby increasing the number of stepwise voltage increases.

If applied higher than ± 25A, the changing range may change too quickly, which may cause a problem that it is difficult to find an appropriate range.

In addition, currents having the same value may be applied to the electromagnetic coils installed on both the left and right sides of the mold 10 in the reverse direction of ±, and currents having different values may be applied.

The current value applied to the left and right short sides of the mold electromagnetic coil 20 is changed step by step until the temperature of both sides of the mold 10 becomes similar to the intensity of the electromagnetic field applied at S20 (S30).

At this time, S30 is a flow rate of the molten steel (2) by using the electromagnetic coil 20 on both sides of the left and right sides of the mold 10 when the temperature difference between the left and right both sides of the mold 10 is more than ± 10 ℃. The electromagnetic field is applied step by step to adjust.

When the temperature difference between the left and right short sides of the mold 10 is reduced to less than ± 10 ° C., the applied electromagnetic field is maintained to maintain the flow rate of the molten steel 2 so that no drift occurs.

In addition, the intensity of the electromagnetic field is gradually changed while maintaining the variation range of the current applied to the electromagnetic coil 20 to ± 15 to 25A for changing the electromagnetic field of S30, thereby changing the flow velocity of the molten steel (2). do.

By measuring the temperature of the short side portion of the mold 10 through the above method, the electromagnetic field applied from the electromagnetic coil 20 is applied to the left and right directions, respectively, thereby changing the flow rate of the molten steel 2 injected into the mold 10. There is an advantage that can be easily adjusted.

And, the surface of the molten steel (2) is stabilized to block the inflow of the mold powder and bubbles to improve the quality of the molten steel (2), the flow in the mold (2) is also stabilized to prevent operation accidents There is also an advantage in securing operability.

The present invention has been described with reference to the preferred embodiments, and those skilled in the art to which the present invention pertains to the detailed description of the present invention and other forms of embodiments within the essential technical scope of the present invention. Could be. Here, the essential technical scope of the present invention is shown in the claims, and all differences within the similar scope should be interpreted as being included in the present invention.

1: nozzle 2: molten steel
10: mold 20: electromagnetic coil
30: temperature sensor 40: control unit

Claims (9)

An electromagnetic coil installed on the front, rear, left, and right outer wall surfaces of the mold to accelerate and decelerate the discharge flow of molten steel discharged from the nozzle to the mold;
A temperature sensor installed at left and right short sides of the mold; And
And a control unit for controlling electromagnetic coils on the left and right sides of the mold outer wall surface detected by the temperature sensor to apply an electromagnetic field to the molten steel discharged from the nozzle. .
The method of claim 1,
The temperature sensor is provided with one or more on the left and right short sides of the mold to measure the temperature of the left and right short sides of the mold, molten steel flow drift reduction device.
The method of claim 1,
The control unit is different from the current mode applied to the left and right electromagnetic coils when the temperature deviation of the left and right short sides of the mold detected by the temperature sensor is greater than the reference value, molten steel flow drift reduction device in the mold.
Measuring the temperature of the short side portion through a temperature sensor respectively installed on the left and right short side portions of the mold to be heated according to the flow phenomenon of molten steel injected into the mold;
Applying an electromagnetic field to molten steel discharged from the nozzle by controlling electromagnetic coils on the left and right sides of the mold outer wall according to the temperature measured by the temperature sensor; And
And changing the current value applied to the mold left and right short side electromagnetic coils step by step until the temperature of the electromagnetic field applied in the step of applying the electromagnetic field approaches the temperature of the left and right short side portions of the mold within a predetermined temperature difference. , Reduction method using molten steel flow drift reduction device in mold.
The method of claim 4, wherein
In the step of applying the electromagnetic field, by applying the EMLS mode to reduce the flow rate of the molten steel to the electromagnetic coil on the outer wall side of the high temperature by measuring the temperature of the left and right short sides of the mold with the respective temperature sensors, the outer wall side of the temperature is low Reduction method using molten steel flow drift reducing device in the mold to control the flow rate of the molten steel by applying the EMLA mode to increase the flow rate of the molten steel in the electromagnetic coil.
6. The method of claim 5,
And a current mode applied to the left and right electromagnetic coils when the temperature deviation of the left and right short sides of the mold detected by the respective temperature sensors is equal to or greater than a reference value.
The method of claim 4, wherein
The changing of the current value may include applying an electromagnetic field in a stepwise manner to adjust the flow rate of molten steel using electromagnetic coils on both sides of the mold short sides when the temperature difference between the left and right short sides of the mold is greater than ± 10 ° C. And maintaining the applied electromagnetic field when the temperature difference of the mold short side portion is less than ± 10 ° C.
The method of claim 4, wherein
The variation range of the current applied to the electromagnetic coil to change the electromagnetic field in the step of changing the current value is ± 15 ~ 25A, reduction method using molten steel flow drift reduction device in the mold.
The method of claim 4, wherein
The temperature sensor is a reduction method using a molten steel flow drift reduction device in one or a plurality of the mold short side is provided to measure the temperature of the left and right short side of the mold.

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