JPH07236958A - Device for controlling position of molten metal surface in continuous molding equipment - Google Patents

Abstract

PURPOSE:To stabilize the position of the molten metal surface and form the ingot of excellent quality by automatically detecting the displacement of the position of the molten metal surface, and adjusting the tilting amount of a drum furnace. CONSTITUTION:A float 8 suspended by a wire 11 is afloat on the molten metal 23 in a tundish 1. This wire 11 is stretched to blocks 9, 10, and a weight plate 12 is mounted on the other end side. An ultrasonic sensor 13 to detect the distance to the weight plate 12 is provided immediately below the weight plate 12. A measuring instrument 18 receives the detected signal from the ultrasonic sensor 13, and this detected signal is converted into the displacement of the position of the molten metal 23. A sequencer 21 preliminarily sets the relationship between the displacement of the position of the surface of the molten metal 23 in the tundish 1 and the appropriate adjustment of the tilting of the drum furnace relative to this displacement, inputs the displacement from the measuring instrument 18 through a digital indicator 20, and controls a drum furnace tilting mechanism 22 by the prescribed adjustment of tilting the drum furnace corresponding to this displacement.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic control device for keeping a molten metal surface position constant in a continuous casting facility.

[0002]

2. Description of the Related Art For example, in a continuous casting facility for copper or copper alloys, in order to obtain a high quality ingot, a molten metal surface in a mold or a tundish for supplying molten metal to this mold is used. It is desirable to carry out casting while keeping the molten metal surface as small as possible. Hereinafter, a conventional example of this technique will be described with three examples.

(1) As shown in FIG. 2, in this continuous casting facility, a molten metal 31 is supplied from a drum furnace 39 into a tundish 30 through a gutter 38, and the tundish 3
From 0, the molten metal 33 is supplied into the mold 32 through the nozzle 34. The atmosphere in the vicinity of the tundish 30 has a very high temperature, and molten metal splashes are present. In addition,
In front of the drum furnace 39, there is a melting furnace (not shown). Then, the float 40 is floated on the molten metal 31 in the tundish 30 by using the round bar 35 having the float 40 at one end and having the scale 36 engraved. The caster uses the scale 36 of the round bar 35.
And the indicator rod 3 hung over the tundish 30
7, the displacement amount of the molten metal surface position of the molten metal 31 was read by moving the scale 36 up and down. And
The caster adjusts the tilt amount of the drum furnace 39 via a tilt mechanism (not shown) of the drum furnace 39, which is composed of a motor and a drive mechanism, according to the displacement amount of the molten metal surface position, and the tundish 3
The amount of molten metal discharged from the drum furnace 39 is adjusted so that the molten metal surface position within 0 is constant, that is, does not fluctuate.

(2) As shown in FIG. 3, in order to automatically control the position of the molten metal 41 in the mold 40,
A nozzle 45 for injecting the molten metal 44 into the mold 40 from the tundish 43, and a float molten metal outlet 47 communicating with the nozzle 45 and having the molten metal 41 in the mold 40.
Some use a combination of floats 46 floating above. That is, the molten metal surface 41 of the molten metal 41 in the mold 40
In the position adjustment of No. 2, when the molten metal surface 42 of the molten metal 41 rises, the float 46 rises as the molten metal surface 42 rises,
By closing the molten metal outlet of the nozzle 45, the inflow of molten metal into the mold 40 is suppressed. On the other hand, when the molten metal surface 42 of the molten metal 41 descends, the float 46 also descends as the molten metal surface 41 descends. The molten metal 44 is injected into the mold 40 by reducing the molten metal outflow resistance of the nozzle 45 (see Japanese Patent Application Laid-Open No. 1-2202352). Reference numeral 48a is a cooling water inlet for supplying cooling water to the mold 40, reference numeral 48b is a cooling water outlet for discharging the cooling water, and reference numeral 49 is an ingot formed by the mold 40.

(3) As shown in FIG. 4, the tundish 50 is composed of an upper chamber 51 and a lower chamber 52, and the molten metal (see metal level AA) injected into the upper chamber 51 passes through a filter 53. Through to the lower chamber 52. Regarding the means for detecting the metal level B-B of the lower chamber 52, a float 55 floating above the metal level B-B is fixed to one end of a lever 54, which lever 54 shows a level change to a conversion device 56, which is converted. The device 56 converts the detected data into a signal. This signal is sent by the power from the power source 58 to the recorder 59 via the transmission line 57 and recorded in the recorder 59. Thereby, a rapid change in the molten metal due to the stop of the molten metal flowing into the upper chamber 51, the free outflow of the molten metal passing through the defect or crack of the filter 53, etc. is immediately recorded. Then, the caster adjusts the tilt amount of the drum furnace via a tilt mechanism (not shown) of the drum furnace (not shown) based on the recording result, and the metal level B-B in the tundish 50 is adjusted. The amount of molten metal discharged from the drum furnace is adjusted so as to be constant (see Japanese Patent Publication No. 61-500320).

[0006]

In the above-mentioned (1), since the displacement amount of the molten metal surface position is visually read and the tilt amount of the drum furnace is manually adjusted, the tilt amount is adjusted. Is inaccurate, that is, an error occurs in the tilt amount to be adjusted, the position of the molten metal surface becomes unstable, and the adjustment work is troublesome. Also, the atmosphere in the vicinity of the tundish is hot and contains splashes of molten metal, which puts the caster at risk. In the case of (2), the position of the molten metal surface is automatically adjusted, but since the float floats on the molten metal surface in the mold, the temperature of the molten metal in the mold changes due to the flow of molten metal flowing out from the float in the mold. There is a problem that the unevenness in location occurs, the balance of the thermal stress generated during solidification of the melt is lost, and as a result, cracks occur in the ingot cross section and the ingot surface that have been cast, and the quality of the ingot is remarkably inferior. is there. The type (3) automatically detects the amount of displacement of the molten metal surface, but like the type (1), the amount of tilt of the drum furnace is manually adjusted. There is a problem that an error occurs and the position of the molten metal becomes unstable, and the adjustment work is troublesome.

The present invention has been made in view of the above-mentioned problems of the prior art, and it is safe by automatically detecting the displacement amount of the molten metal surface position and adjusting the drum furnace tilt amount. , Reduce the error of the tilt amount to be adjusted,
It is an object of the present invention to provide a molten metal surface position control device in a continuous casting facility that can stabilize the molten metal surface position and form a high quality ingot.

[0008]

To achieve the above object, a molten metal surface position control device of the present invention is provided with a drum furnace in which the amount of molten metal discharged is adjusted by a drum furnace tilting mechanism. In a continuous casting facility in which molten metal is supplied to the mold for forming an ingot from this tundish, a float floating above the molten metal in the tundish, a weight, and the float at one end However, a wire to which the weight is attached to the other end, respectively, wire guide means for hanging the wire, a distance sensor for detecting the distance to the weight, which is provided directly below the weight, Input a detection signal from the distance sensor,
A measuring device for converting the detection signal into a displacement amount of the molten metal surface position of the molten metal in the tundish, and a correspondence between the displacement amount and an appropriate drum furnace tilt adjustment amount for the displacement amount are set in advance. , Inputting the displacement amount from the measuring device, and automatically controlling the drum furnace tilting mechanism so that the drum furnace is driven by a predetermined drum furnace tilting adjustment amount corresponding to the displacement amount. It is characterized by being composed of a sequencer. Also, two pulleys can be used as the one in which the distance sensor is buried in the floor or the ground, or as a part of the wire guiding means. Further, a digital display for resetting the displacement amount input from the measuring device to a reference point and displaying the displacement amount with respect to the reference point is provided between the measuring device and the sequencer. The distance sensor is an ultrasonic sensor.

[0009]

In the invention according to claim 1 configured as described above, in the unlikely event that the molten metal surface position in the tundish fluctuates, this fluctuation is transmitted to the float and the float also fluctuates,
As a result, the weight also fluctuates via the wire, and the distance between this weight and the distance sensor directly below the weight changes. This distance is detected by a distance sensor, and the detected value is input to a measuring device, where it is converted into a displacement amount of the molten metal surface position of the molten metal in the tundish. Then, the sequencer inputs the displacement amount from the measuring device, and automatically operates the drum furnace tilting mechanism so that the drum furnace is driven by a predetermined drum furnace tilt adjustment amount corresponding to the displacement amount. To control. That is, when the molten metal surface position is higher than the specified position, the sequencer adjusts the tilt amount of the drum furnace to reduce the amount of molten metal discharged, while the molten metal surface position is lower than the specified position. If the amount of hot water discharged from the drum furnace increases, and the displacement of the molten metal surface position increases,
The drum furnace tilt adjustment amount is also set to be large. As a result, the amount of hot water discharged from the drum furnace is adjusted so as to suppress the fluctuation of the molten metal surface position in the tundish. The reason why the displacement of the float is indirectly detected through the displacement of the weight is that the temperature cannot be detected in the vicinity of the high temperature tundish. Claim 2
In the invention described in (1), the distance sensor is not exposed to the high temperature atmosphere of the tundish. In the invention according to claim 3, the wire is smoothly moved by the pulley.
In the invention according to claim 4, since a certain displacement amount is set as a reference point and the displacement amount from this reference point can be known, it is possible to cope with a change in the reference molten metal surface position due to the replacement of the tundish. As in the invention described in claim 5, a sensor utilizing laser or ultrasonic waves can be used as the distance sensor, but it is preferable to use a safe ultrasonic sensor.

[0010]

An embodiment of the present invention will be described with reference to the drawings. As shown in FIG. 1, the continuous casting facility for copper or copper alloy according to the present embodiment is provided with a drum furnace 6 in which the amount of molten metal discharged is adjusted by a drum furnace tilting mechanism 22, and the drum furnace 6 is connected via a gutter 5. The molten metal 23 is supplied into the tundish 1, and further, the molten metal 24 is supplied from the tundish 1 through the nozzle 2 into the mold 3 for forming the ingot. The atmosphere in the vicinity of the tundish 1 becomes very hot, and the molten metal splashes present, which is dangerous. A melting furnace (not shown) is provided in front of the drum furnace 6. In the present embodiment, the molten metal surface position 24 of the molten metal 4 in the mold 3 has the configuration described below.
Is stabilized by stabilizing the position of the molten metal 23 in the tundish 1.

On the molten metal 23 in the tundish 1, a float 8 suspended by a wire 11 described later floats.
The wire 11 is extended and guided by two pulleys 9 and 10, and a disk-shaped weight plate 12 is attached to the other end side. The float 8 is made of a mass of refractory material, and the weight plate 1
The weight of 2 is such that the float 8 cannot be lifted by that weight. The wire 11 is always stretched. Further, the pulleys 9 and 10 are rotatably attached to the ends of the pulley bracket 17, respectively.
7 is connected to the magnet piece 15 via a support rod 16.
The magnet piece 15 is magnetically fixed to the iron bracket 14 projecting from the side surface of the tundish 1. The above-described two pulleys 9 and 10, the pulley bracket 17, the support rod 16 and the like constitute a wire guide means 26. Immediately below the weight plate 12, an ultrasonic sensor 13 as a distance sensor for detecting the distance to the weight plate 12 is provided. The ultrasonic sensor 13 is affected by the high temperature atmosphere of the tundish 1 due to thermal influence. It is buried in the floor or the ground 25 so as not to receive it. Although a sensor using a laser may be used as the distance sensor 13,
In this case, the laser emits upward, which is somewhat dangerous. Further, the reason why the displacement amount of the float 8 is indirectly detected by detecting the displacement of the weight plate 12 is that the temperature cannot be detected in the vicinity of the high temperature tundish 1 due to the temperature influence.

The measuring device 18 inputs a detection signal from the ultrasonic sensor 13, converts this detection constant signal into a displacement amount of the molten metal surface position of the molten metal 23 in the tundish 1, and displays the displacement amount. The digital display 20 is provided with a reset button 19 for setting the input signal from the measuring device 18 to a zero point (reference point), that is, resetting it, and displays the displacement amount from the reference point in units of ± 0.01 mm. Sequencer 2
In FIG. 1, the correspondence between the displacement amount of the molten metal 23 in the tundish 1 and the appropriate drum furnace tilt adjustment amount corresponding to this displacement amount is set in advance, and the measuring device 18 is operated via the digital display 20. The displacement amount is input from, and an internal calculation is performed so that the drum furnace 6 is driven by the predetermined drum furnace tilt adjustment amount corresponding to the displacement amount of the molten metal surface position of the molten metal 23.
The drum furnace tilting mechanism 22 is automatically controlled.
The correspondence between the displacement amount of the molten metal 23 in the tundish 1 and the appropriate drum furnace tilt adjustment amount with respect to this displacement amount has been previously obtained experimentally prior to regular continuous casting. . As the ultrasonic sensor 13, the measuring device 18, and the digital display 20, product numbers UD-310, UD-300, and RV- manufactured by Keyence Corporation are used, respectively.
3 was used.

Next, the operation of the molten metal surface position control apparatus of this embodiment will be described. As shown in FIG. 1, if the level of the molten metal 23 in the tundish 1 fluctuates, this fluctuation is transmitted to the float 8 and the float 8 also fluctuates. As a result, the weight plate 12 also passes through the wire 11. It fluctuates, and the distance between the weight plate 12 and the ultrasonic sensor 13 changes. Of course, when the float 8 rises, the weight plate 12 descends by the moving amount (displacement amount) of the float 8. The distance is detected by the ultrasonic sensor 13, and the detected value is input to the measuring device 18,
Here, the amount of displacement of the molten metal 23 in the tundish 1 is converted and displayed. Of course, this displacement amount may be positive or negative. Then, this displacement amount is input to the sequencer 21 via the digital display 20, and the sequencer 21 outputs the predetermined drum furnace tilt adjustment amount corresponding to the input displacement amount via the drum furnace tilting mechanism 22. The drum furnace 6 is automatically controlled. That is, the sequencer 21 reduces the amount of molten metal discharged from the drum furnace 6 when the position of the molten metal 23 is higher than the specified position, and when the position of the molten metal 23 is lower than the specified position. , Increase the amount of tap water in the drum furnace 6, and
The tilt adjustment amount of the drum furnace 6 is set to increase as the displacement amount of the molten metal surface position increases. As a result, the amount of molten metal discharged from the drum furnace 6 can be changed to the molten metal 2 in the tundish 1.
It is adjusted so as to suppress the fluctuation of the molten metal surface of No. 3.

As described above, in the present embodiment, the displacement amount of the molten metal surface 23 in the tundish 1 and the adjustment of the drum furnace tilt amount are automatically performed, so that it is safe and the tilt amount is accurate. Can be adjusted, that is, the error of the tilt amount can be reduced, and the molten metal level can be stabilized. Moreover,
Since the float is not floated on the molten metal 4 in the mold 3, the balance of thermal stress is not lost when the molten metal 4 in the mold 3 is solidified, and a high quality ingot can be formed. In addition, the caster presses the reset button 19 of the digital display 20,
An arbitrary position of the molten metal surface of the molten metal 23 in the tundish 1 is set to a zero point (reference point), the displacement from the reference point is displayed, and the caster can know this at a glance. This is effective when the reference molten metal surface position changes when the tundish 1 is replaced. Furthermore, tundish 1
When exchanging the magnets with different sizes, the magnet piece 15 is removed from the bracket 14, and the wire guiding means 2 including the two pulleys 9 and 10 and the pulley supporting bracket 17 is provided.
6 can be exchanged.

[0015]

Since the present invention is configured as described above, it has the following effects. The invention according to claim 1 is safe by automatically detecting the displacement amount of the molten metal surface position in the tundish and adjusting the tilt amount of the drum furnace, and the tilt amount of the drum furnace can be accurately adjusted. The position of the molten metal can be stabilized, and moreover,
Since no float floats on the molten metal in the mold, a good quality ingot can be formed. Further, the displacement detection of the float is indirectly performed through the displacement detection of the weight apart from the tundish, so that the displacement detection is not affected by temperature and the displacement detection accuracy is improved. In the invention according to claim 2, the distance sensor is not exposed to a high temperature atmosphere due to the tundish, and the detection accuracy is further improved. According to the third aspect of the invention, since the wire is smoothly moved, the displacement detection accuracy does not deteriorate even if the displacement of the float is detected through the displacement of the weight plate. In addition to the above effects, the invention according to claim 4 is capable of determining the molten metal surface position at a reference point at an arbitrary position and knowing the variation from this reference point, and therefore the reference molten metal surface caused by the replacement of the tundish Can respond to changes in position. The invention according to claim 5 becomes even safer by using the ultrasonic sensor that does not harm the human body.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram of an embodiment of a molten metal surface position control device in a continuous casting facility of the present invention.

FIG. 2 is a diagram showing a main part of a conventional continuous casting facility.

FIG. 3 is a view showing a main part of another conventional continuous casting facility.

FIG. 4 is a diagram showing a main part of still another conventional continuous casting facility.

[Explanation of symbols]

 1 Tundish 2 Nozzle 3 Mold 4 Melt 5 Gutter 6 Drum Furnace 7 Gutter 8 Float 9, 10 Pulley 11 Wire 12 Weight Plate 13 Ultrasonic Sensor (Ultrasonic Displacement Meter) 14 Bracket 15 Magnet Piece 16 Support Rod 17 Pulley Bracket 18 Measurement Device 19 Reset button 20 Digital display 21 Sequencer 22 Drum furnace tilting mechanism 23 Molten metal 24 Level position 25 Floor or ground 26 Wire guide means

Claims (5)

[Claims] 1. A drum furnace in which the amount of molten metal discharged is adjusted by a drum furnace tilting mechanism, the molten metal is supplied from the drum furnace into the mold for forming an ingot. In a continuous casting facility where molten metal is supplied, a float floating above the molten metal in the tundish, a weight, a wire having the float attached to one end and the weight attached to the other end, and the wire Wire guiding means for guiding, a distance sensor provided directly below the weight for detecting a distance to the weight, and a detection signal input from the distance sensor, and the detection signal is input in the tundish. A measuring device for converting the molten metal into a displacement amount of the molten metal surface position, and a correspondence between the displacement amount and an appropriate drum furnace tilt adjustment amount corresponding to this displacement amount is set in advance, A sequencer for inputting the displacement amount from a measuring device and automatically controlling the drum furnace tilting mechanism so that the drum furnace is driven by a predetermined drum furnace tilting adjustment amount corresponding to the displacement amount. And a molten metal surface position control device in a continuous casting facility. 2. The molten metal position control device in a continuous casting facility according to claim 1, wherein the distance sensor is embedded in a floor or the ground. 3. The molten metal position control device in a continuous casting facility according to claim 1, wherein two pulleys are used as a part of the wire guiding means. 4. A digital display for resetting the displacement amount input from the measuring device to a reference point and displaying the displacement amount with respect to the reference point is provided between the measuring device and the sequencer. The molten metal position control device in the continuous casting equipment according to any one of claims 1 to 3. 5. The molten metal position control device in a continuous casting facility according to claim 1, wherein the distance sensor is an ultrasonic sensor.