JP2006136930A - Twin roll type continuous casting machine and twin roll type continuous casting method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent the wear of side gates from being caused by the contact of solidified shells. <P>SOLUTION: When molten steel 106 is fed into a moving die composed of recessed rolls 101, 102, and side gates 103, 104, the molten steel 106 is cooled at the roll surfaces (surfaces other than step parts), so as to turn to solidified shells 111, 112, and both the solidified shells 111, 112 are pressure-contacted, and the same is pulled out as a cast slab 113. Since heat insulating materials (ceramic coatings) are applied to the circumferential faces of the step parts 101a, 101b, 102a, 102b as both the edge parts of the rolls, heat release does not progress in this parts, and solidified shells are not formed. In this way, a gap is formed between both the ends of the solidified shells 111, 112 and the side gates 103, 104, and the solidified shells 111, 112 are prevented from being in contact with the side gates 103, 104, thus the wear of the side gates 103, 104 is prevented. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a twin-roll continuous casting machine and a twin-roll continuous casting method, and is devised to greatly reduce the side weir wear and extend the side weir life.

  The continuous casting machine continuously casts molten steel that has been refined, and directly produces a slab (slab or strip). The continuous casting method using a continuous casting machine is less segregated and has good surface quality compared to conventional ingot-making and ingot-making methods, and is suitable for producing steel plate slabs.

  As a continuous casting machine, there is a twin-roll type continuous casting machine using a synchronous twin-roll type mold (moving mold) in which a mold moves together with a slab.

  FIG. 8 shows a general example of a twin roll type continuous casting machine 010. In this twin roll type continuous casting machine 010, a pair of oppositely rotating rolls 011 and 012 are arranged close to each other in parallel at the same height position, and both axial ends of the rolls 011 and 012 are It is partitioned by side weirs 013 and 014 that are crimped to the roll end face. Molten steel 016 is supplied through a nozzle 015 to the internal space (hot water reservoir) of the moving mold formed by the rolls 011 and 012 and the side weirs 013 and 014.

  When the rolls 011 and 012 rotate in opposite directions (rotating the molten steel 016 downward), the molten steel 016 is cooled by coming into contact with the rolls 011 and 012. As a result, the surfaces of the rolls 011 and 012 are respectively A solidified shell is formed. Both of these solidified shells grow as the roll rotates, and are pressed and integrated at the minimum gap portions of the rolls 011 and 012 and are taken out as a cast slab 017.

  Next, an example of a twin roll type continuous casting machine in which the roll shape is devised so as to increase the thickness of the cast slab will be described using the one shown in JP-A-59-118249.

  FIG. 9 shows a twin roll type continuous casting machine disclosed in Japanese Patent Application Laid-Open No. 59-118249, and FIG. 10 is a view taken along the line AA of FIG.

As shown in FIGS. 9 and 10, a pair of rolls 10, 11, side weirs 12, 13 that are crimped to the end faces of the rolls 10, 11 to partition the roll end face side, and a dam 14 that is in contact with the rolls 10, 11. , 15 is the hot water reservoir. Molten steel 16 is supplied to the hot water reservoir.
At both ends of the roll 10, step portions 10a and 10b are formed in a flange shape. Similarly, step portions 11 a and 11 b are formed in a flange shape at both ends of the roll 11.

  When the rolls 10 and 11 are rotated, the molten steel 16 is cooled by coming into contact with the surfaces of the rolls 10 and 11 (including the surfaces of the stepped portions 10a, 10b, 11a, and 11b), and the solidified shells 17 and 18 are brought into contact. Is formed. The solidified shells 17 and 18 grow as the roll rotates. And it formed in the outer periphery of step part 10a, 10b among the solidification shells 17 in the minimum gap part where the clearance gap between step part 10a and step part 11a and the gap between step part 10b and step part 11b become the smallest. The part and the part formed in the outer periphery of step part 11a, 11b among the solidification shells 18 are press-contacted and integrated by the narrow pressure by step part 10a, 10b and step part 11a, 11b. As a result, both ends of the solidified shell 17 and the solidified shell 18 are pressed and integrated, and both the solidified shells 17 and 18 are joined in a bag binding shape as shown in FIG. Thus, the slab 19 is obtained.

  The slab 19 in a state in which the solidified shells 17 and 18 are pressed into a bag binding shape at the minimum gap portion and the molten steel 16 is left in the central portion is drawn out of the rolls 10 and 11 and conveyed, and is cooled in the middle of conveyance. As a result, the molten steel 16 in the center portion also solidifies.

  In the example shown in FIG. 9 and FIG. 10, the stepped portions 10 a and 10 b and the stepped portions 11 a and 11 b having a narrow gap can be pressed at the ends of the solidified shells 17 and 18. The slab 17 that can be pressed into a bag binding shape and pulled out from the rolls 10 and 11 is in a molten state at the center, but the peripheral surface is solidified. Become. Thus, since the clearance gap between the rolls 10 and 11 can be widened, the thickness of the slab 19 manufactured can be made thick. Since the thickness of the slab 19 can be increased in this way, the amount of slab production can be increased, and the production of steel plates having various thicknesses can be dealt with.

JP 59-118249 A JP 2000-246399 A Japanese Patent Laid-Open No. 9-0295106 JP 2001-219247 A Japanese Patent Laid-Open No. 3-155438

  By the way, even if it is the twin roll type continuous casting machine shown in FIG. 8 or the twin roll type continuous casting machine shown in FIG. 9 and FIG. 10, the solidified shell formed on the roll surface is the side during casting. Touching the weir. Since the solidified shell moves as the roll moves, the side weir is worn by the moving solidified shell. For this reason, there was a problem that the life of the side weir was short. In addition, since the liquid leak of molten steel will arise if wear of a side dam progresses, when wear advances to some extent, it is necessary to replace a side dam. When the side weir is replaced, casting must be stopped and productivity is lowered. Therefore, it is desired to extend the life of the side weir as much as possible.

  FIG. 11 is an enlarged view showing the minimum gap portion in a plan view in the twin-roll continuous casting machine shown in FIG. 8, and is formed on the end surface of the solidified shell 018 formed on the surface of the roll 011 and the surface of the roll 012. The end surface of the solidified shell 019 is in a state where the side weir 013 is worn.

  That is, the surface of the side weir 013 that is to be pressure-bonded to the drums 011 and 012 is initially flat, but the side weir 013 is worn by the solidified shells 018 and 019. The state which the part which contacts an edge part is dented is shown.

  An object of this invention is to provide the twin roll type continuous casting machine and the twin roll type continuous casting method which can extend the lifetime of a side dam in view of the said prior art.

The structure of the present invention that solves the above problem is to supply molten steel into a moving mold composed of a pair of rolls rotating in opposite directions and a pair of side weirs crimped to the end surfaces of the rolls. In a twin-roll continuous casting machine that draws out a slab formed by pressure-contacting a solidified shell solidified on the surface of
Of the peripheral surface of the roll, a heat insulating material is applied to a portion that circulates in the circumferential direction on both ends with respect to the roll axial direction.
Moreover, continuous casting is performed using this apparatus.

Further, the configuration of the present invention supplies molten steel into a moving mold composed of a pair of rolls rotating in opposite directions and a pair of side weirs crimped to the end faces of the rolls, and solidifies on the surface of each roll. In a twin roll type continuous casting machine that draws out the slab formed by pressure-contacting the solidified shell from the gap between the rolls,
Of the peripheral surface of the roll, a vaporizing material applying device for applying a vaporizing material is provided on both ends of the roll axial direction and in a circumferential direction.
Moreover, continuous casting is performed using this apparatus.

Further, the configuration of the present invention supplies molten steel into a moving mold composed of a pair of rolls rotating in opposite directions and a pair of side weirs crimped to the end faces of the rolls, and solidifies on the surface of each roll. Pull out the slab formed by pressure-contacting the solidified shell from the gap between the rolls,
In the twin roll continuous casting machine, the roll has a diameter at both ends along the roll axis direction larger than the diameter of the center portion of the roll, and has step portions at both ends in the roll axis direction.
A heat insulating material is applied to the peripheral surface of the step portion of the roll.
Moreover, continuous casting is performed using this apparatus.

Further, the configuration of the present invention supplies molten steel into a moving mold composed of a pair of rolls rotating in opposite directions and a pair of side weirs crimped to the end faces of the rolls, and solidifies on the surface of each roll. Pull out the slab formed by pressure-contacting the solidified shell from the gap between the rolls,
In the twin roll continuous casting machine, the roll has a diameter at both ends along the roll axis direction larger than the diameter of the center portion of the roll, and has step portions at both ends in the roll axis direction.
A vaporizing material applying device for applying a vaporizing material to the peripheral surface of the step portion of the roll is provided.
Moreover, continuous casting is performed using this apparatus.

  In the structure of the present invention, the heat insulating material is a ceramic coating, a metal, or a composite material.

  In the present invention, since the heat insulating material is applied to the portions that circulate in the circumferential direction at both ends with respect to the roll axis direction (the peripheral surface of the step portion in the case of the concave roll), the heat removal does not proceed in this portion and the solidified shell is not formed. . For this reason, a gap is generated between the end face of the solidified shell and the side weir, the side weir is not worn by the solidified shell, and the life of the side weir is extended.

  Moreover, in this invention, since the vaporizing material is provided to the part (circumferential surface of a step part in a concave roll) of the circumferential surface of a roll by the both ends side with respect to a roll axial direction, and the circumference (circumferential surface of a step part in a concave roll). When this portion enters the molten steel, bubbles are generated from the vaporized material. In this portion, heat removal does not proceed and a solidified shell is not formed. For this reason, a gap is generated between the end face of the solidified shell and the side weir, the side weir is not worn by the solidified shell, and the life of the side weir is extended.

Embodiments of the present invention will be described below in detail with reference to the drawings.
Here, the “concave roll” used in the embodiment of the present invention will be described first. A “concave roll” refers to a “roll whose diameter at both ends along the axial direction of the roll is larger than the diameter of the central portion of the roll”.

For example, as the “concave roll”, as shown in FIG. 1A, the roll R has stepped portions D at both ends, and as shown in FIG. 1B, both ends of the roll R are tapered. Having a step portion D, and having a step portion D at both ends as shown in FIG. 1 (c), the roll R has a drum shape whose diameter gradually decreases toward the center in the axial direction. There are various types of rolls.
If such a concave roll is used for at least one roll, the solidified shell can be pressed into a bag-like shape, and the cast slab can be made thick.

  A twin-roll continuous casting machine according to Embodiment 1 of the present invention will be described with reference to FIG. 2 and FIG. 3 which is a view taken along the line BB in FIG.

  In the twin roll type continuous casting machine 100 according to the first embodiment, a pair of concave rolls 101 and 102 rotating in opposite directions are arranged close to each other in parallel at the same height position. Both ends in the axial direction are partitioned by side weirs 103 and 104 that are crimped to the end face of the roll. Molten steel 106 is supplied through the nozzle 105 to the internal space (hot water reservoir) of the movable mold formed by the concave rolls 101 and 102 and the side weirs 103 and 104.

The concave roll 101 has step portions 101a and 101b after both ends of the roll expand in a tapered shape. The concave roll 102 has stepped portions 102a and 1021b after both ends of the roll expand in a tapered shape.
In addition, the arrangement of the concave rolls 101 and 102 is set so that the step portion 101a and the step portion 102a are in contact with each other and the step portion 101b and the step portion 102b are in contact with each other in the minimum gap portion.

  And on the peripheral surfaces of the stepped portions 101a, 101b, 102a, 102b (that is, the portions of the peripheral surfaces of the concave rolls 101, 102 that circulate around both ends in the circumferential direction in the roll axis direction (roll width direction)). In addition, a heat insulating material is applied (in FIG. 3, hatching is drawn on a portion where the heat insulating material is applied). Specifically, the ceramic coating is performed by spraying a porous ceramic.

Thus, it is a special technical feature of the present invention that the peripheral surfaces of the step portions 101a, 101b, 102a, and 102b are provided with a heat insulating material.
Note that the specific method for applying the heat insulating material is not only coating but also fitting a ring-shaped heat insulating material or forming the roll so that the material of the roll is the heat insulating material only in that portion. May be.
Moreover, you may perform the coating of a heat insulating material suitably also during casting.

  When the concave rolls 101 and 102 rotate in directions opposite to each other, the molten steel 106 is cooled by contacting the surface of the concave rolls 101 and 102 (this surface does not include the surfaces of the step portions 101a, 101b, 102a, and 102b). Thus, the solidified shells 111 and 112 are formed. The solidified shells 111 and 112 grow as the roll rotates. The end of the solidified shell 111 and the end of the solidified shell 112 are pressed and integrated at the minimum gap where the gap between the concave roll 101 and the concave roll 102 is the smallest. At this time, both ends of the solidified shell 111 and the solidified shell 112 are pressed and integrated, and both the solidified shells 111 and 112 are joined in a bag binding shape as shown in FIG. 3 while leaving the molten steel 106 at the center. Thus, the slab 113 is obtained.

  The slab 113 in a state in which the solidified shells 111 and 112 are pressed in a bag-bound form at the minimum gap portion and the molten steel 106 is left in the center portion is drawn out from the concave rolls 101 and 102 and is transported, and is cooled in the middle of transport. As a result, the molten steel 106 in the center portion also solidifies.

  During the casting described above, the molten steel 106 supplied to the inner space (pouring pool) of the moving mold is removed from the surfaces of the concave rolls 101 and 102 except for the surfaces of the step portions 101a, 101b, 102a, and 102b. Heat is promoted to form solidified shells 111 and 112. However, since the surface of the step portions 101a, 101b, 102a, and 102b is provided with a heat insulating material, heat removal does not proceed on the step portion surface, and a solidified shell is not formed on the step portion surface.

Thus, a solidified shell is not formed on the surfaces of the step portions 101a, 101b, 102a, and 102b. In other words, a solidified shell is not formed on both ends of the circumferential surface of the concave rolls 101 and 102 with respect to the roll axis direction. . As a result, as shown in FIG. 3, a gap is formed between the solidified shells 111 and 112 and the side weirs 103 and 104, and the solidified shells 111 and 112 do not contact the side weirs 103 and 104. Therefore, the side weirs 103 and 104 are not worn by the contact of the solidified shells 111 and 112, and the life of the side weirs 103 and 104 is extended.
As described above, the life of the side weirs 103 and 104 is extended, so that the productivity of casting is improved.

  Further, since the concave rolls 101 and 102 are arranged so that the stepped portion 101a and the stepped portion 102a are in contact with each other, and the stepped portion 101b and the stepped portion 102b are in contact with each other, the gap between the recessed roll 101 and the concave roll 102 There is also an advantage that can be kept constant with high accuracy.

  Next, a twin-roll continuous casting machine 100-1 according to Example 2 of the present invention will be described with reference to FIG. Note that the same portions as those in the first embodiment are denoted by the same reference numerals and redundant description is omitted, and different portions are mainly described.

In the first embodiment, heat insulating material is applied to the peripheral surfaces of the step portions 101a, 101b, 102a, and 102b. In Example 2, heat insulating material is applied to the peripheral surfaces of the step portions 101a, 101b, 102a, and 102b. I have not rubbed.
Instead, the second embodiment includes vaporizing material applying devices 120, 121, 122, and 123 that apply gelled vaporizing material to the peripheral surfaces of the step portions 101a, 101b, 102a, and 102b.

  For example, silicone or grease oil is used as the vaporizing material. Such a vaporizing material generates a gas when heated by the molten steel 106, and this gas creates a gap between the circumferential surface of the stepped portions 101 a, 101 b, 102 a, 102 b and the molten steel 106, and the stepped portion circumferential surface Prevents the formation of solidified shells in Since this vaporizing material is in a gel form, when it is applied to the peripheral surface of the step portion, it does not flow to other parts. In FIG. 4, hatching is drawn in the portion where the vaporizing material is applied.

  The arrangement positions of the vaporizing material applying devices 120, 121, 122, and 123 may be any positions that can contact the peripheral surfaces of the step portions 101a, 101b, 102a, and 102b at positions where the molten steel 106 and the cast slab 113 are not present. .

In addition, as a vaporization material provision apparatus, not only the coating type thing mentioned above but a spraying type thing may be used.
The configuration of other parts is the same as that of the first embodiment.

  At the time of casting, the molten steel 106 supplied to the inner space (water pool portion) of the moving mold is heat-extracted in the portions of the surfaces of the concave rolls 101 and 102 excluding the surfaces of the step portions 101a, 101b, 102a and 102b. Is promoted to become solidified shells 111 and 112. However, on the surfaces of the step portions 101a, 101b, 102a, and 102b, the vaporized material is vaporized and bubbles are generated. Therefore, heat removal does not proceed on the step portion surface, and a solidified shell is not formed on the step portion surface.

Thus, a solidified shell is not formed on the surfaces of the step portions 101a, 101b, 102a, and 102b. In other words, a solidified shell is not formed on both ends of the circumferential surface of the concave rolls 101 and 102 with respect to the roll axis direction. . As a result, as shown in FIG. 4, a gap is formed between the solidified shells 111 and 112 and the side weirs 103 and 104, and the solidified shells 111 and 112 do not contact the side weirs 103 and 104. Therefore, the side weirs 103 and 104 are not worn by the contact of the solidified shells 111 and 112, and the life of the side weirs 103 and 104 is extended.
As described above, the life of the side weirs 103 and 104 is extended, so that the productivity of casting is improved.

  The same effect can be obtained by combining Example 1 and Example 2. In Example 1 and Example 2, other types of concave rolls (see FIG. 1) can also be used.

  Next, a twin-roll continuous casting machine 100A according to Embodiment 3 of the present invention will be described with reference to FIG. 6 which is a view taken along the line CC in FIGS. Note that the same portions as those in the first embodiment are denoted by the same reference numerals and redundant description is omitted, and different portions are mainly described.

  In the twin-roll continuous casting machine 100A according to the third embodiment, flat rolls 101A and 102A (that is, columnar shapes having no stepped portions) are used as rolls.

  In Example 3, the heat insulating material is given to the circumferential surfaces of the rolls 101 </ b> A and 102 </ b> A at both ends with respect to the roll axis direction and in the circumferential direction (in FIG. 6, the portions with the heat insulating material applied). Is hatched). Specifically, the ceramic coating is performed by spraying a porous ceramic.

Note that the specific method for applying the heat insulating material is not only coating but also fitting a ring-shaped heat insulating material or forming the roll so that the material of the roll is the heat insulating material only in that portion. May be.
Moreover, you may perform the coating of a heat insulating material suitably also during casting.

  When the rolls 101A and 102A rotate in directions opposite to each other, the molten steel 106 is cooled by contacting the surfaces of the rolls 101A and 102A (this surface does not include a surface provided with a heat insulating material), and the solidified shells 111 and 112 Is formed. The solidified shells 111 and 112 grow as the roll rotates. Then, the solidified shell 111 and the solidified shell 112 are pressed and integrated at the minimum gap portion where the gap between the roll 101A and the roll 102A is the smallest.

  The cast slab 113 formed by press-contacting the solidified shells 111 and 112 at the minimum gap is drawn out from the rolls 101A and 102A and conveyed.

  In the casting described above, the molten steel 106 supplied to the inner space (hot water reservoir) of the moving mold is accelerated by heat removal at the portion of the surfaces of the rolls 101A and 102A excluding the surface to which the heat insulating material is applied, so that the solidified shell. 111, 112. However, since heat insulating material is applied to the circumferential surfaces of the rolls 101A and 102A on both ends in the roll axis direction and around the circumferential direction, heat removal does not proceed on this surface and a solidified shell is not formed.

As described above, the solidified shell is not formed in the circumferential surfaces of the rolls 101A and 102A at both end sides with respect to the roll axis direction and in a portion that makes one round in the circumferential direction. As a result, as shown in FIG. 6, a gap is formed between the solidified shells 111 and 112 and the side weirs 103 and 104, and the solidified shells 111 and 112 do not contact the side weirs 103 and 104. Therefore, the side weirs 103 and 104 are not worn by the contact of the solidified shells 111 and 112, and the life of the side weirs 103 and 104 is extended.
As described above, the life of the side weirs 103 and 104 is extended, so that the productivity of casting is improved.

  Next, a twin-roll continuous casting machine 100A-1 according to Example 4 of the present invention will be described with reference to FIG. Note that the same portions as those in the third embodiment are denoted by the same reference numerals and redundant description is omitted, and different portions are mainly described.

In Example 3, the heat insulating material is applied to the circumferential surfaces of the rolls 101A and 102A at both ends in the roll axis direction and in the circumferential direction, but in Example 4, the heat insulating material is applied to the roll peripheral surface. I don't give it.
Instead, in the fourth embodiment, the vaporizing material applying devices 120A, 121A, and 122A for applying the gel vaporizing material to the portions of the peripheral surfaces of the rolls 101A and 102A that are both ends in the roll axial direction and make a round in the circumferential direction. , 123A.

  For example, silicone or grease oil is used as the vaporizing material. Such a vaporized material generates a gas when heated by the molten steel 106, and this gas creates a gap between the both ends of the roll peripheral surface and the molten steel 106, and solidifies at both ends of the roll. Prevents shell formation. Since this vaporizing material is in the form of a gel, if it is applied to both end portions of the roll peripheral surface, it will not flow to other portions. In addition, in FIG. 7, hatching is drawn in the part which applied the vaporization material.

  The arrangement positions of the vaporizing material applying devices 120A, 121A, 122A, and 123A may be any positions where the molten steel 106 and the cast slab 113 can be in contact with both ends of the roll peripheral surface.

In addition, as a vaporization material provision apparatus, not only the coating type thing mentioned above but a spraying type thing may be used.
The configuration of other parts is the same as that of the third embodiment.

  At the time of casting, the molten steel 106 supplied to the inner space (hot water reservoir) of the moving mold is accelerated to remove heat at the portions of the surfaces of the rolls 101A and 102A excluding the portions on both ends in the roll axis direction. Thus, the solidified shells 111 and 112 are obtained. However, in the surface of the rolls 101A and 102A, the vaporized material is vaporized and bubbles are generated in the portions on both ends with respect to the roll axial direction, so that the heat removal does not proceed and the solidified shell is not formed in these portions.

Thus, a solidified shell is not formed in the portions on both ends of the surfaces of the rolls 101A and 102A with respect to the roll axis direction. As a result, as shown in FIG. 7, a gap is formed between the solidified shells 111 and 112 and the side weirs 103 and 104, and the solidified shells 111 and 112 do not contact the side weirs 103 and 104. Therefore, the side weirs 103 and 104 are not worn by the contact of the solidified shells 111 and 112, and the life of the side weirs 103 and 104 is extended.
As described above, the life of the side weirs 103 and 104 is extended, so that the productivity of casting is improved.
The same effect can be obtained by combining Example 3 and Example 4.

Explanatory drawing which shows the various examples of a concave roll. The front view which shows the twin roll type continuous casting machine which concerns on Example 1 of this invention. The BB arrow line view of FIG. The top view which shows the twin roll type continuous casting machine which concerns on Example 2 of this invention. The front view which shows the twin roll type continuous casting machine which concerns on Example 3 of this invention. The top view which shows the twin roll type continuous casting machine which concerns on Example 3 of this invention. The top view which shows the twin roll type continuous casting machine which concerns on Example 4 of this invention. The block diagram which shows the conventional twin roll type continuous casting machine. The block diagram which shows the conventional twin roll type continuous casting machine. FIG. 10 is an AA arrow view of FIG. 9. Explanatory drawing which shows the abrasion state of a side dam.

Explanation of symbols

100,100A, 100-1,100A-1 Twin roll type continuous casting machine 101,102 Recessed roll 101a, 101b, 102a, 102b Stepped part 101A, 102A Roll 103,104 Side weir 105 Nozzle 106 Molten steel 111,112 Solidified shell 113 Cast slabs 120, 121, 122, 123, 120A, 121A, 122A, 123A vaporizer application device

Claims (10)

Molten steel is supplied into a moving mold composed of a pair of rolls rotating in opposite directions and a pair of side weirs crimped to the end faces of the rolls, and the solidified shell solidified on the surface of each roll is pressed against each other. In a twin roll continuous casting machine that pulls out the slab from the gap between the rolls,
A twin roll type continuous casting machine characterized in that a heat insulating material is applied to a part of the circumferential surface of the roll that circulates in the circumferential direction at both ends with respect to the roll axial direction. Molten steel is supplied into a moving mold composed of a pair of rolls rotating in opposite directions and a pair of side weirs crimped to the end faces of the rolls, and the solidified shell solidified on the surface of each roll is pressed against each other. In a twin roll continuous casting machine that pulls out the slab from the gap between the rolls,
A twin-roll type continuous casting method characterized in that continuous casting is performed using a roll in which a heat insulating material is applied to a portion of the circumferential surface of the roll that is both ends in the roll axial direction and that makes a round in the circumferential direction. Molten steel is supplied into a moving mold composed of a pair of rolls rotating in opposite directions and a pair of side weirs crimped to the end faces of the rolls, and the solidified shell solidified on the surface of each roll is pressed against each other. In a twin roll continuous casting machine that pulls out the slab from the gap between the rolls,
A twin-roll type continuous casting machine comprising a vaporizing material applying device for applying a vaporizing material to a portion of the peripheral surface of the roll that circulates in the circumferential direction on both ends with respect to the roll axial direction. Molten steel is supplied into a moving mold composed of a pair of rolls rotating in opposite directions and a pair of side weirs crimped to the end faces of the rolls, and the solidified shell solidified on the surface of each roll is pressed against each other. In a twin roll continuous casting machine that pulls out the slab from the gap between the rolls,
A twin-roll continuous casting method, characterized in that a vaporizing material is applied to a portion of the circumferential surface of the roll that circulates in the circumferential direction at both ends with respect to the roll axial direction. Molten steel is supplied into a moving mold composed of a pair of rolls rotating in opposite directions and a pair of side weirs crimped to the end faces of the rolls, and the solidified shell solidified on the surface of each roll is pressed against each other. Pull out the slab from the gap between the rolls,
In the twin roll continuous casting machine, the roll has a diameter at both ends along the roll axis direction larger than the diameter of the center portion of the roll, and has step portions at both ends in the roll axis direction.
A twin roll type continuous casting machine, wherein a heat insulating material is applied to a peripheral surface of a step portion of the roll. Molten steel is supplied into a moving mold composed of a pair of rolls rotating in opposite directions and a pair of side weirs crimped to the end faces of the rolls, and the solidified shell solidified on the surface of each roll is pressed against each other. Pull out the slab from the gap between the rolls,
In the twin roll continuous casting machine, the roll has a diameter at both ends along the roll axis direction larger than the diameter of the center portion of the roll, and has step portions at both ends in the roll axis direction.
A twin-roll continuous casting machine, wherein continuous casting is performed using a roll having a heat insulating material applied to a peripheral surface of a step portion of the roll. Molten steel is supplied into a moving mold composed of a pair of rolls rotating in opposite directions and a pair of side weirs crimped to the end faces of the rolls, and the solidified shell solidified on the surface of each roll is pressed against each other. Pull out the slab from the gap between the rolls,
In the twin roll continuous casting machine, the roll has a diameter at both ends along the roll axis direction larger than the diameter of the center portion of the roll, and has step portions at both ends in the roll axis direction.
A twin-roll type continuous casting machine comprising a vaporizing material applying device for applying a vaporizing material to a peripheral surface of a step portion of the roll. Molten steel is supplied into a moving mold composed of a pair of rolls rotating in opposite directions and a pair of side weirs crimped to the end faces of the rolls, and the solidified shell solidified on the surface of each roll is pressed against each other. Pull out the slab from the gap between the rolls,
In the twin roll continuous casting machine, the roll has a diameter at both ends along the roll axis direction larger than the diameter of the center portion of the roll, and has step portions at both ends in the roll axis direction.
A twin-roll type continuous casting method, wherein a vaporizing material is applied to a peripheral surface of a step portion of the roll. In claim 1 or claim 5,
The twin roll continuous casting machine, wherein the heat insulating material is a ceramic coating, a metal, or a composite material. In claim 2 or claim 6,
The twin roll continuous casting method, wherein the heat insulating material is a ceramic coating, a metal, or a composite material.

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