JP2651380B2 - Twin belt continuous casting machine - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a twin-belt continuous caster in which heating at an end in a belt width direction applied to prevent belt deformation is improved.

[Conventional technology]

FIG. 2 shows an outline of a conventional twin belt continuous casting machine. 1,1 ′
Is a metallic (mainly steel) endless belt, 2,
2 'is a belt driving roll, 3, 3' are belt positioning top rolls, 4, 4 'are steering rolls for preventing the belt from meandering, and the driving rolls 2, 2' are provided.
The pair of belts 1, 1 'driven by the rollers are guided and moved by the above-mentioned rolls in the directions of arrows W, W'. Between the positioning top rolls 3, 3 'and the driving rolls 2, 2', the pair of belts 1, 1 'move downward in parallel with each other with a space C therebetween.

The portion of the pair of belts 1, 1 'descending with the interval C parallel between the positioning rolls 3, 3' and the driving rolls 2, 2 'is shown near the both ends of the belts 1, 1'. A pair of side molds is arranged so as to be sandwiched by the belts 1 and 1 ', and a mold section extending up and down in a rectangular cross section surrounded by the belts 1 and 1' and the side molds is formed. Five,
Reference numeral 5 'denotes a water cooling pad for cooling the belts 1 and 1' from the back (the surface opposite to the mold section is referred to as the back in the present specification).

20 is a ladle for holding molten metal, 6 is the above ladle 20
A tundish 7 for containing molten metal from the mold is a pouring nozzle provided in the tundish 6 and is opened at the upper part of the mold part. Reference numeral 8 denotes a molten metal surface in the mold portion, and reference numeral 9 denotes a slab slab formed in the mold portion.

In a conventional twin-belt continuous caster having such a configuration, a pair of endless metal belts 1, 1 'are driven at constant speeds by rolls 2, 2', respectively.
Molten metal is continuously injected from a tundish 6 by a pouring nozzle 7 into the mold section having a rectangular cross section formed between the pair of belts and a pair of side molds positioned at the belt ends. Endlessly driven belt 1,
Since 1 'is cooled from the back by the water-cooling pads 5, 5' as described above, the molten metal injected between the belts 1, 1 'is sequentially cooled and solidified to form a slab slab 9, The slab 9 is fed downward away from the belts 1,1 'moving around the rolls 2,2'.

[Problems to be solved by the invention]

FIG. 3 shows a deformed portion of the belt of the conventional twin belt continuous casting machine. Normally, in the case of steel, a thickness of 0.6 to 1.5 mm is selected in consideration of fatigue strength. At this time, the surface in contact with the molten metal rises to about 200 ° C and causes thermal expansion,
The non-contact surface does not stretch because it is not heated by the molten metal, and this causes deformation as shown in FIG. 3 in the belt width direction. Therefore, conventionally, as a measure for preventing the deformation, a tension is applied to the belt within the elastic range at room temperature. However, it was difficult to suppress the deformation only by the additional tension applied to the belt, and the thickness variation of the slab formed between the pair of belts was up to ± 5 mm.

An object of the present invention is to provide a twin belt continuous caster in which such belt deformation is prevented.

[Means for solving the problem]

Since the deformation of the belt is caused by the difference in thermal expansion in the width direction, in the present invention, the non-contact portion with the molten metal is heated to the same temperature as the contact portion. That is, the present invention solves the above-mentioned problem in the twin-belt continuous caster including a pair of side molds and a pair of belts rotating while sandwiching the mold, and is movable according to the width of the slab to be manufactured. A pair of belts forming a mold portion by sandwiching a pair of side molds,
A twin-belt continuous caster provided with heating means for heating a non-contact portion of the belt in a width direction with a slab to substantially the same temperature as a contact portion of the belt with the slab, wherein the belt has a side surface from an edge portion. Electromagnetic induction heating means installed in the entire width of the moving range of the mold so as to extend in the width direction of the belt, and at an edge of the belt, the space between the belt and the other portion is set apart from other parts; Provided is a twin belt continuous caster having a device for cooling a belt portion facing an electromagnetic induction heating means up to an inner end in a direction.

[Action]

In the twin belt continuous caster according to the present invention, the side mold can be moved in the width direction of the belt so as to change the width of the slab, and in changing the width of the slab, the slab of the belt and The non-contact portion was surely heated.

Moreover, in the twin-belt continuous caster according to the present invention, the electromagnetic induction heating means is disposed at a distance from the belt at the edge of the belt, so that the electromagnetic induction heating means is electromagnetically applied to the belt end by the electromagnetic induction heating means. It is possible to prevent the belt portion from being heated non-uniformly due to concentrated heating of the edge portion of the belt.

Thereby, in the present invention, even if the width of the slab is changed, the non-contact portion with the slab in the belt width direction is always heated to almost the same temperature as the contact portion with the slab by the electromagnetic induction heating means, and the belt There is no difference in thermal expansion in the width direction, local deformation of the belt is prevented even under weak tension, and variation in the thickness of the cast slab is suppressed.

〔Example〕

 One embodiment of the present invention will be described with reference to FIG.

In this embodiment, the same parts as those of the conventional twin-belt continuous caster shown in FIG. 2 are denoted by the same reference numerals, and description thereof will be omitted.

In this embodiment, the electromagnetic induction heating device 24 having one U-turn coil 25 and having a U-shaped silicon steel plate 26 for preventing electromagnetic interference of the coil at a portion facing the belt of the coil 25 is used as the belt 1, 1 'Attached at the position of the molten metal surface 8 with an interval d on the back surface on both sides. The electromagnetic induction heating device 24 extends inward from the edge of the belt in the width direction of the belt so as to cover the entire moving range of the side mold 13 in the width direction.

Further, a water partition 27 that can move in the width direction of the belt is provided on the side of the electromagnetic induction heating device 24 facing the belt, and the water partition 27 is synchronized with the movement of the side mold 13 by a device (not shown). , Ie, at the boundary between the mold 13 and the molten metal 11. The coil 25 is internally water-cooled by cooling water flowing in a hole 29 provided inside the coil 25, and the electromagnetic induction heating device 24 is provided on the outside of the water partition 27 by the cooling water 21 flowing in the direction indicated by the arrow in FIG. Is to be water-cooled.

In the present embodiment, a portion from the edge of the belt 1, 1 'not in contact with the molten metal (slab) 11 to the inside of the side mold 13 is heated by the electromagnetic induction heating device 24. The temperature is almost the same as the contacting part. On the other hand, the belt portion facing the electromagnetic induction heating device 24 in the portion of the belt 1, 1 'where the molten metal exists inside the side mold 13 is the cooling water.
Since the belt is cooled by water and does not heat this portion of the belt, the contact portion of the belt with the molten metal is heated by the electromagnetic induction heating device 24 in addition to the molten metal, and the temperature is prevented from rising.

Further, in the twin belt continuous caster according to the present embodiment, the belts 1,
At the edge A of 1 ', the coil 25 of the electromagnetic induction heating device 24 is separated from the other parts by the belt 1, 1'.

For example, when the distance d between the belt and the coil electromagnetic induction heating device other than the belt edge is 5 mm, it is appropriate that the distance at the edge is 10 mm and the length of the portion A is 10 mm or less.

When heating the non-contact part of the belt with the molten metal,
At the end of the belt, the temperature rises from other parts and the belt is overheated. Especially in the heating by the electromagnetic induction heating device 24,
The electromagnetic quantity is concentrated on the belt end, and this portion is heated strongly.

In this embodiment, at the edge portion A of the belt, the coil 25
The amount of electromagnetism acting on the belt edge by separating the belt from the belt more than the other parts is the same as the other parts,
Thereby, the heating temperature in the width direction of the belt becomes uniform, and local deformation of the belt is prevented.

In this way, in the present embodiment, even if the width of the slab is changed by moving the side mold, a uniform temperature distribution can always be realized in the width direction of the belts 1 and 1 ', and There is no variation in thickness.

In this embodiment, the belt thickness: 1.0 mm Belt heating temperature: 200 ° C. Belt rotation speed: 10 m / min Belt cooling water flow rate: 5 m / sec One-turn coil length: 520 mm Distance between coil and belt (d …… 5mm Distance between coil and belt edge (B) …… 10mm Edge A where coil is separated ……………………………………………………………………………………………………………………………………………………………………………………………………
A temperature gradient as shown in FIG. C is obtained, local deformation in the belt width direction is suppressed to 1 mm or less, local deformation at the edge disappears (belt tension 5 kg / mm ² ), and the maximum variation in the thickness of the slab is reduced by 0.5. mm or less.

〔The invention's effect〕

As described above, the twin belt continuous caster according to the present invention is provided with the electromagnetic induction heating means for heating the non-contact portion with the slab in the width direction of the belt to substantially the same temperature as the contact portion with the slab of the belt. Twin belt continuous casting machine, wherein the electromagnetic induction heating means is installed extending in the belt width direction from the edge of the belt to the entire region of the moving range of the side mold, and the belt and the belt at the edge of the belt Are spaced apart from other parts. Therefore, in the twin belt continuous caster according to the present invention, the non-contact portion with the slab is heated while preventing the edge portion of the belt from being strongly heated by the electromagnetic induction heating means to make the temperature of the belt non-uniform. In addition, the temperature of the belt can be kept uniform.

[Brief description of the drawings]

1A and 1B show an embodiment of the present invention, wherein FIG. 1A is a front view thereof, FIG. 1B is a sectional view taken along line II of FIG.
2C is a graph showing the temperature distribution of the belt, FIG. 2 is an explanatory diagram of a conventional twin-belt continuous caster, and FIG. 3 is a diagram showing the relationship between the belt and the molten metal in the conventional twin-belt continuous caster and the belt. It is explanatory drawing which shows the amount of deformation of the width direction of FIG. 1,1 '... Belt 2,2' ... Drive roll 3,3 '... Positioning top roll 7 ... Pouring nozzle 8 ... Molten surface 11 ... Molten metal 13 ... Side mold 21 ... Cooling water 24 Electromagnetic induction heating device 25 Coil 26 Silicon steel plate 27 Water partition

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Koichi Hirata 4-6-22 Kannon Shinmachi, Nishi-ku, Hiroshima City, Hiroshima Prefecture Inside the Hiroshima Research Laboratory, Mitsubishi Heavy Industries, Ltd. (72) Inventor Naoyuki Nagai 4-chome Kannon Shinmachi, Nishi-ku, Hiroshima City, Hiroshima Prefecture No. 6-22 Mitsubishi Heavy Industries, Ltd. Hiroshima Research Laboratory (72) Inventor Junkichi Yoneda 4-6-22 Kanon Shinmachi, Nishi-ku, Hiroshima City, Hiroshima Prefecture Mitsubishi Heavy Industries, Ltd. Hiroshima Works (56) References JP-A-61-99541 JP, A) Actually open sho 59-58550 (JP, U)

Claims (1)

(57) [Claims] 1. A pair of belts forming a mold portion by sandwiching a pair of side molds movable in accordance with the width of a slab to be manufactured, and a non-contact portion of the belt in the width direction of the belt with the slab. A twin-belt continuous caster provided with a heating means for heating to substantially the same temperature as a contact portion with a slab, wherein the twin-belt continuous caster is installed extending in the belt width direction from the edge of the belt to the entire region of the moving range of the side mold. And an electromagnetic induction heating means at an edge of the belt, the distance from the belt being set apart from other parts, and a belt part facing the electromagnetic induction heating means from the side mold to the inner end in the belt width direction. A twin-belt continuous caster comprising a cooling device.