JP2010269359A - Method of hot reusing tundish focusing on temperature difference between precedent charge and subsequent charge - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a technique for preventing a blockage of a nozzle, and surely pouring molten steel from a tundish to a mold, during hot reusing the tundish. <P>SOLUTION: An inside of a tundish 1 is once emptied, when continuous casting of a precedent charge is ended, and supply of the molten steel of a subsequent charge shall be started to the tundish 1, within 3 hours after the end of the continuous casting of the precedent charge, without heating the tundish 1. Molten steel temperature T [&deg;C] of the subsequent charge shall satisfy a formula (1) (wherein T<SB>LL</SB>[&deg;C] in the formula (1) means liquidus temperature of the molten steel of the precedent charge). <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a method for hot reuse of tundish.

  Generally, so-called hot reuse of tundish is performed in which the cold maintenance process is omitted and the tundish is continuously used hot. As this type of technology, Patent Document 1 discloses a technology that focuses on ensuring the quality of a cast slab at an early stage of casting. Specifically, this document 1 states that it is important to cool the tundish surface temperature rapidly. On the other hand, if the tundish surface temperature is lowered too much, it is poured from the ladle into an empty tundish. Since the temperature of the molten steel is excessively lowered and the casting of molten steel from the tundish to the mold is hindered, it becomes impossible to cast, so the surface temperature of the tundish should be at least 1000 ° C or more. It is said.

Japanese Patent No. 3093617

  However, actually, even if the surface temperature of the tundish is ensured to be 1000 ° C. or more, the nozzle (nozzle means a flow path from the tundish to the mold) is blocked, and the tundish In some cases, the casting of molten steel into the mold was hindered and the casting was impossible.

  The present invention has been made in view of the above points, and its main purpose is to prevent the nozzle from being clogged when the tundish is reused hot, and to ensure the injection of molten steel from the tundish to the mold. The purpose is to provide technology to realize hot water.

Means and effects for solving the problems

  The problems to be solved by the present invention are as described above, and the inventors of the present invention, after intensive research, have determined that the relationship between the liquidus temperature of the molten steel of the previous charge and the molten steel temperature of the next charge is blocking the nozzle. As a result, the following invention was completed.

According to the aspect of the present invention, hot reuse of tundish is performed by the following method. That is, the molten steel supplied from the ladle is temporarily received and the tundish for pouring the molten steel into the mold through the immersion nozzle connected to the discharge hole formed at the bottom is reused hot. When the previous charge continuous casting is completed, the tundish is emptied once and the molten steel of the next charge is supplied to the tundish within 3 hours from the end of the previous charge continuous casting without heating the tundish. Shall begin to do. The molten steel temperature T [° C.] for the next charge satisfies the following formula (1). However, in the following formula (1), T _LL [° C.] means the liquidus temperature of the precharged molten steel.

  According to the above method, when the inside of the tundish is emptied, it is possible to remelt the residual metal that has been inevitably left and solidified in or near the discharge hole without being completely discharged. When the dish is reused hot, it is possible to prevent clogging of the nozzle, thereby realizing a reliable pouring of molten steel from the tundish to the mold.

Perspective view of tundish Cross section of the discharge hole formed in the bottom of the tundish and its surroundings Explanatory drawing of measuring method and measuring condition of molten steel temperature of next charge

(Definition of terms)
・ Next charge: When the tundish is reused hot, it means the charge to be cast.
-Pre-charge: This means the charge that was cast immediately before the tundish was reused hot.
Liquidus temperature TLL [° C.]: Means a value obtained from the chemical composition of molten steel using the Hirai equation. The Hirai formula is expressed by the following formulas (2) and (3). For details, refer to “The Japan Iron and Steel Institute, Steel Handbook 3rd edition, 1st edition, manufacturing basis, 4. Solidification phenomenon, 4.1.5 Liquid phase. "Line temperature and solidus temperature calculation method (Yoshio Miyashita) p.205". However, in the following formulas (2) and (3), C [wt%] is the carbon content of the molten steel, and similarly, Si [wt%] is the silicon content, Mn [wt%] is the manganese content, Cr [Wt%] means chromium content, and Ni [wt%] means nickel content.
Nozzle: means a flow path (molten steel flow path 23) from the tundish to the mold.
Nozzle blockage: Blocking of the flow path (molten steel flow path 23) from the tundish to the mold is meant.

  As is well known, when paying attention to the casting path of a typical continuous casting facility, there are a curved continuous casting facility and a vertical bending continuous casting facility. The former has an arc path portion, a correction path portion, and a horizontal path portion along the casting path from the mold, and the latter has a vertical path portion upstream of the arc path portion, and floats inclusions in the molten steel. Is intended. Focusing on the cross-sectional shape of the slab cast by the continuous casting equipment, there are slabs having an aspect ratio of 2 or more and blooms having a cross-sectional shape of 2 or less, and billets having a square or round cross-sectional shape. The application object of the present invention is continuous casting belonging to all the above categories. Hereinafter, in the present specification, as an example, an example in which the present invention is applied to a curved continuous casting facility for bloom will be described.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  As shown in FIG. 1, the tundish 1 temporarily receives molten steel supplied from a ladle 2 schematically indicated by a two-dot chain line, and is connected to a discharge hole 4 formed in the bottom portion 3. This is for pouring the mold 6 through the immersion nozzle 5. In the bottom 3 of the tundish 1 of the present embodiment, discharge holes 4 for four strands are formed. The tundish 1 communicates with the molten steel holding chamber 8 having a sufficient volume so that the molten steel temperature to the four strands becomes uniform, and is supplied from the ladle 2 to the molten steel holding chamber 8. And a tundish lid for suppressing a temperature drop of the molten steel held in the molten steel holding chamber 8. The molten steel communication chamber 9 for directly receiving the molten steel and transferring it to the molten steel holding chamber 8 is formed. 10 is provided so as to be attachable to and detachable from the side portion 11 that partitions the molten steel holding chamber 8. In the tundish lid 10, a heating hole 12 is formed at a position coinciding with the discharge hole 4 in a plan view. An oxygen nozzle for blowing oxygen into the heating hole 12 is inserted into the discharge hole 4. On the other hand, by blowing oxygen at a predetermined flow rate, it is possible to actively dissolve the residual metal fixed in or near the discharge hole 4. With the above configuration, the molten steel supplied from the ladle 2 to the molten steel communication chamber 9 moves to the molten steel holding chamber 8, is poured into the mold 6 through the discharge hole 4 and the immersion nozzle 5, and is illustrated in the mold 6. By forming a solidified shell that does not, a bloom 13 as indicated by a two-dot chain line (however, the interior is in an unsolidified state immediately below the mold 6) is continuously cast.

  Next, a cross-sectional structure around the discharge hole 4 will be described with reference to FIG. That is, as shown in FIG. 2, the bottom 3 of the tundish 1 is composed of a thick refractory 14 and an iron skin 15 covering the refractory 14. And the said discharge hole 4 formed in this bottom part 3 is formed in cross-sectional substantially drum shape as illustration. The discharge hole 4 is provided with a sliding nozzle 16 for controlling the flow rate of the molten steel poured into the mold 6. The sliding nozzle 16 includes a fixed first sliding nozzle 17 that is fixedly attached to the bottom 3 and a movable second sliding nozzle 18 that can move relative to the first sliding nozzle 17 in the horizontal direction. And is composed of.

  The first sliding nozzle 17 is cylindrical and is formed so that the outer peripheral surface is narrowed from the lower end toward the upper end, and is inserted and fixed from below into the discharge hole 4 having a substantially drum shape in cross section. The upper nozzle 19 and a perforated flat plate-shaped upper slide plate 20 fixed from below to the upper nozzle 19 are configured. Similarly, the second sliding nozzle 18 is fixed to the lower slide plate 21 from below with a perforated flat plate-like lower slide plate 21 configured to be slidable relative to the upper slide plate 20. And a cylindrical lower nozzle 22 to which a substantially illustrated immersion nozzle 5 is connected. And the molten steel flow path 23 used for pouring the molten steel currently hold | maintained in the tundish 1 to the casting_mold | template 6 of FIG. 1 is shown by the discharge hole 4, the sliding nozzle 16, and the immersion nozzle 5 as shown in FIG. With the above configuration, the opening of the sliding nozzle 16 can be freely adjusted by sliding the second sliding nozzle 18 relative to the first sliding nozzle 17 in the horizontal direction. It has become. In the state shown in FIG. 2, the opening degree of the sliding nozzle 16 is 0%, that is, the sliding nozzle 16 is closed.

  Next, continuous casting of steel using the tundish 1 will be described. Hereinafter, starting from the steady state of continuous casting, the continuous casting is finished, the inside of the tundish 1 is emptied, the molten steel of the next charge is supplied to the tundish 1 and the continuous casting is resumed.

(Steady state of continuous casting)
In a continuous state of continuous casting, molten steel is supplied at a predetermined flow rate from the ladle 2 capable of holding approximately 250 ton of molten steel to the molten steel communication chamber 9, and the molten steel supplied to the molten steel communication chamber 9 continues to the molten steel holding chamber 8. Has been moved. At this time, approximately 40 to 50 tons of molten steel is always held in the molten steel holding chamber 8, and a known antioxidant (heat insulating material) is floated on the meniscus of the molten steel. Antioxidation and moderate heat retention are achieved. The sliding nozzle 16 shown in FIG. 2 is set to a desired opening degree corresponding to the casting speed, and the molten steel in the molten steel holding chamber 8 is poured into the mold 6 through the molten steel passage 23 at a predetermined flow rate. . As shown in FIG. 1, the solidified shell (bloom 13) formed in the mold 6 is further solidified to the inside by being conveyed further downstream, so that the so-called semi-finished bloom 13 is formed. Is formed.

  When the remaining amount of the molten steel in the ladle 2 becomes a predetermined value or less, the supply of molten steel from the ladle 2 that has become almost empty to the molten steel communication chamber 9 is forcibly stopped, and the ladle 2 is separated from the tundish 1. Transport in the direction. At the same time, the ladle 2 with a full tank is newly conveyed to the position of the two-dot chain line shown in FIG. In this way, continuous casting of the same steel type can be continued continuously over a plurality of charges.

(At the end of continuous casting)
When changing the steel type to be continuously cast, as a general rule, the inside of the tundish 1 is temporarily emptied. That is, when the remaining amount of the precharged molten steel held in the molten steel holding chamber 8 of the tundish 1 falls below a predetermined amount, the opening degree of the sliding nozzle 16 in FIG. Interrupt hot water. This is to prevent slag typified by an antioxidant in the tundish 1 from flowing into the mold 6. The above-mentioned “predetermined amount” means, for example, an amount when the meniscus of the molten steel held in the molten steel holding chamber 8 falls below a height of 5 cm from the bottom surface of the molten steel holding chamber 8. In the present embodiment, the “end point of continuous casting” means a time point when the opening degree of the sliding nozzle 16 is 0%.

  In this state, in the tundish 1, the molten steel slightly below a predetermined amount and the slag suspended on the meniscus of the molten steel remain. Next, in order to temporarily empty the inside of the tundish 1, the remaining molten steel and slag are discharged from the tundish 1 shown in FIG. However, in reality, the molten steel or slag trapped in each discharge hole 4 shown in FIG. 2 cannot be completely discharged out of the tundish 1 only by using the discharge hole 4. In this way, the molten steel and slag that could not be discharged by the above-described discharging operation continue to remain in the tundish 1 as residual metal or residual slag. It is said that these residual bullion and residual slag can be suppressed to a total of 2 ton or less in the applicant's facility.

(Resumption of continuous casting)
When the continuous casting of the precharge is completed as described above, the ladle 2 containing the precharged molten steel is conveyed in a direction away from the tundish 1, and a molten steel of a steel type different from the precharged molten steel is accommodated. The ladle 2 is conveyed to the tundish 1. Then, a new steel type of molten steel (hereinafter also referred to as molten steel of the next charge) starts to be supplied from the ladle 2 to the molten steel communication chamber 9 of the tundish 1. The molten steel of the next charge supplied to the molten steel communication chamber 9 flows into the molten steel holding chamber 8 from the molten steel communication chamber 9 and mixes with the residual metal and residual slag remaining in the molten steel holding chamber 8, and eventually, The molten steel holding chamber 8 is filled. At this time, the sliding nozzle 16 in FIG. 2 is still in a closed state, and when the molten steel meniscus in the molten steel holding chamber 8 reaches the molten metal surface level in the steady state of continuous casting described above, the sliding nozzle 16 To start pouring molten steel of the next charge into the mold 6.

  In the present embodiment, a specific operation is performed from the end of the continuous casting to the restart. That is, the tundish 1 is not heated from the end of the continuous casting until the molten steel of the next charge starts to be supplied to the molten steel communication chamber 9 of the tundish 1. This is for preventing the surface oxidation of the tundish 1 and consequently maintaining the quality of the slab at a high level. When the tundish 1 is heated, the surface oxidation of the tundish 1 is caused by oxygen contained in the combustion gas of the heating burner.

  Further, the time from the end of the continuous casting of the previous charge to the start of supplying the molten steel of the next charge to the molten steel communication chamber 9 of the tundish 1 is within 3 hours. This is because if the tundish 1 is empty and a lot of time has passed, the surface temperature of the tundish 1 itself will drop excessively and heat will be greatly removed until the molten steel of the next charge is poured into the mold 6. Because it will be done. As is well known, the temperature of the molten steel poured into the mold 6 is important for realizing stable continuous casting.

Furthermore, the molten steel temperature T [° C.] of the next charge satisfies the following formula (1). However, in the following formula (1), T _LL [° C.] means the liquidus temperature of the precharged molten steel.

  Here, a measurement method and measurement conditions of the molten steel temperature T [° C.] of the next charge will be described in detail with reference to FIG. 3 is a cross-sectional view obtained by cutting the tundish 1 along a vertical cross section including the center line of the heating hole 12 of FIG. As shown in FIG. 3, in order to measure the molten steel temperature T [° C.] of the next charge, until the meniscus 24 of the molten steel in the molten steel holding chamber 8 reaches the molten metal level in the steady state of the continuous casting described above. Waiting and when this hot water level is reached, a scraping rod (not shown) is inserted into the heating hole 12, and the antioxidant 25 added anew on the meniscus 24 is scraped using the scraping rod, and the meniscus 24 is partially To expose. In the state of FIG. 3, the scraping rod is pulled out from the heating hole 12, and the temperature measuring rod 7 provided with the temperature measuring probe 26 at the tip is similarly inserted into the heating hole 12 substantially vertically. And when this temperature measuring rod 7 is stabbed into said exposed meniscus 24 and the temperature measuring probe 26 is immersed in molten steel about 150-200 mm on the basis of the meniscus 24, the output voltage value of this temperature measuring probe 26 is set. Read and convert this output voltage value to temperature as appropriate. The temperature obtained in this way is adopted as the above-mentioned “molten steel temperature T [° C.] for the next charge”. In addition, as the heating hole 12 into which the temperature measuring rod 7 is inserted, if the measured value of “the molten steel temperature T [° C.] of the next charge” is the same, any one of the four heating holes 12 as shown in FIG. However, if different, the heating hole 12 located at the most upstream side of the molten steel flow in the molten steel holding chamber 8 is adopted. In the present embodiment, as shown in FIG. 1, the heating hole 12 located at the most upstream of the flow of molten steel in the molten steel holding chamber 8 (in other words, closest to the molten steel communication chamber 9) is heated by the third strand. Hole 12 is formed. In this embodiment, the heating hole 12 corresponding to a 3rd strand shall be employ | adopted as the heating hole 12 which inserts the temperature measuring rod 7 from said situation.

<Test>
Hereinafter, the test for confirming the technical effect of the hot reuse method of the tundish 1 which concerns on this embodiment is demonstrated. Each numerical range described above is reasonably supported by the following confirmation test.

<Tests and indicators>
First, an index used for evaluation of each confirmation test will be described.
-Nozzle blockage In each test, when the meniscus of the molten steel in the molten steel holding chamber 8 reaches the molten metal surface level in the steady state of the continuous casting described above, the sliding nozzle 16 is opened and the mold 6 is opened. The pouring of molten steel for the next charge shall be started. At this time, when the molten steel of the next charge poured into the mold 6 immediately stagnate and the molten steel amount of the molten steel of the next charge poured into the mold 6 was within 1 ton, in the test, the tundish 1 was hot. When reusing, it shall be evaluated that nozzle clogging has occurred. On the other hand, when the molten steel of the next charge to the mold 6 is stagnant, but the molten steel amount of the molten steel of the next charge poured into the mold 6 exceeds 1 ton, or when the molten metal itself continues without stagnation In the test, when the tundish 1 is reused hot, it is evaluated that the nozzle blockage can be prevented. In addition, the amount of molten steel of the molten steel of the next charge poured into the casting_mold | template 6 can be measured with the rotation speed of the roll for a measurement in a continuous casting machine after solidification.

<Test, common test method>
As a general rule, operation in accordance with the above-described embodiment is performed. If nozzle clogging occurs, if the nozzle clogging occurs only with one strand, continuous casting was continued with the remaining three strands, but it occurred with two or more strands. In the event of stagnation, continuous casting was stopped immediately and proper cleaning was performed.

<Test and common test conditions>
Next, test conditions common to each confirmation test will be described.
Mold size: 600mm x 380mm (for bloom)
Steel type: A correspondence table was prepared in Table 1 below. In any steel type, nickel is made as zero as possible.

Each column in Table 1 is as follows.
“C wt%” means carbon content.
“Si wt%” means silicon content.
“Mn wt%” means manganese content.
“Cr wt%” means the chromium content.
“T _LL wt%” means the liquidus temperature obtained from the Hirai equation.

<Test, individual test conditions and individual test results>
Next, individual test conditions and test results of each confirmation test are shown in Table 2 below.

Each column in Table 2 is as follows.
-“ΔT ° C.” of “next charge” means a so-called superheat. The degree of superheat is the difference between the actual temperature of the molten steel and the liquidus temperature determined from the components of the molten steel.
“T−T _LL ° C.” means a value obtained by subtracting the liquidus temperature TLL [° C.] of the previous charge from the molten steel temperature T [° C.] of the next charge. When this value was 10 or more, “◯” was also written, and “x” was written otherwise.
“Empty time P hr” means the time (in units of hours) from the end of the continuous casting of the previous charge until the molten steel of the next charge starts to be supplied to the molten steel communication chamber 9 of the tundish 1. When this time was within 3, “○” was written together, and “x” was written otherwise.
-“Evaluation Nozzle blockage” means the evaluation result of each test evaluated based on the above-mentioned index. That is, the test evaluated that nozzle clogging occurred based on the above index was evaluated as “x”, and the other tests were evaluated as “◯”.

<Test: Supplementary explanation>
・ Test No. 1, the steel type of the precharge is steel type A described in Table 1, and the liquidus temperature TLL [° C.] of steel type A is 1527. The steel type of the next charge was steel type B in Table 1, and the molten steel temperature T [° C.] of the next charge was 1553. Therefore, “T−T _LL ° C.” was 26. That is, the molten steel temperature T [° C.] for the next charge was sufficiently higher than the liquidus temperature TLL [° C.] for the previous charge. The free time P [hr] was 0.2. That is, the state where the tundish 1 was empty was at most about 12 minutes. In this case, continuous casting of the next charge could be started without any problem without nozzle clogging.
・ Test No. 7, the steel type of the pre-charge is steel type A, and the liquidus temperature TLL [° C.] of steel type A is 1527. The steel type of the next charge was steel type H in Table 1, and the molten steel temperature T [° C.] of the next charge was 1496. Therefore, “T−T _LL ° C.” was −32. That is, the molten steel temperature T [° C.] of the next charge was considerably lower than the liquidus temperature TLL [° C.] of the previous charge. The free time P [hr] was 0.2. In this case, nozzle clogging occurred and it was necessary to give up continuous casting of the next charge.

(Summary)
As described above, in the above embodiment, the hot reuse of the tundish 1 is performed by the following method. That is, after the previous charge continuous casting is completed, the tundish 1 is emptied and the tundish 1 is heated within 3 hours from the end of the previous charge continuous casting without heating the tundish 1. Shall begin to supply. The molten steel temperature T [° C.] for the next charge satisfies the following formula (1).

  According to the above method, as shown in Table 2 above, when the tundish 1 is reused hot, the nozzle can be prevented from being clogged, thereby realizing a reliable pouring of molten steel from the tundish 1 to the mold. We were able to. The nozzle can be prevented from being blocked by the above method, as expressed most simply in the above equation (1), with respect to the liquidus temperature TLL [° C.] of the previous charge. The molten steel temperature T [° C.] is sufficiently high, so that when the inside of the tundish 1 is emptied, the residual metal that has inevitably remained in the discharge hole 4 or in the vicinity thereof and has been solidified without being completely discharged. It is thought that it was because it was able to remelt.

  The above test No. Considering 7, in order to satisfy the above formula (1) on the assumption that the steel type of the previous charge is steel type A and the steel type of the next charge is steel type H, the molten steel temperature T [° C.] of the next charge is set to 1537. There is a need. However, in that case, the superheat degree ΔT [° C.] of the molten steel of the next charge becomes 66. In this case, even if molten steel of the next charge is poured into the mold 6, the temperature is so high that no healthy solidified shell growth can be expected in the mold 6, so-called vertical cracks, molten metal leaks, and breakouts. Will cause abnormal operation. In this sense, the combination of the steel type of the previous charge and the steel type of the next charge should be judged after sufficiently examining whether the relationship of the above formula (1) can be established without any problem.

Claims (1)

When the molten steel supplied from the ladle is temporarily received and the tundish for pouring the molten steel into the mold through the immersion nozzle connected to the discharge hole formed at the bottom is reused hot. ,
Once the previous charge continuous casting is completed, the tundish is emptied once, and the next charge of molten steel begins to be supplied to the tundish within 3 hours from the end of the previous charge continuous casting without heating the tundish. age,
The molten steel temperature T [° C.] of the next charge shall satisfy the following formula (1):
It is characterized by
Hot reuse of tundish, focusing on the temperature difference between the previous charge and the next charge.
However, in the following formula (1), T _LL [° C.] means the liquidus temperature of the precharged molten steel.

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