JPH0137223B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) This invention relates to improvements in molds used in horizontal continuous casting.

(Prior art) Horizontal continuous casting has been put into practical use through the development of a break ring and the adoption of an intermittent drawing drive.

The break ring is installed between the hot tundish nozzle and the mold wall, which is cooled from the back with a water-cooled jacket, and receives heat from the high-temperature molten steel and is cooled by the mold wall, resulting in a very large heat load. It is generally formed into an integral ring shape, and extremely severe taper processing is required at the contact area to increase the contact ratio between the sealing part and the mold wall, and the mold wall is made of different materials. When assembling at room temperature, it is necessary to use a method such as press-fitting or shrink-fitting to prevent gaps from forming between the two under high temperature conditions.

Furthermore, there is a limit to the manufacturing size of integral ring-shaped break rings, and it is currently difficult to make large ones.However, in order to cast large stepped slabs, large ring-shaped break rings are In use, there was a drawback that during casting, a gap was likely to be formed at the taper joint between the mold wall end face and the break ring due to the difference in expansion rate, resulting in leakage of molten steel.

FIG. 1 is a cross-sectional view of a main part of a mold in a conventional horizontal continuous casting facility for casting polygonal slabs, and FIG. 2 is a cross-sectional view taken along the line aa in FIG. 1.

In the figure, 1 is a tundish, 2 is a tundish nozzle, and 3 is a mold wall divided into a plurality of parts connected to the tundish nozzle 2 with a nozzle ring 4 and a break ring 5 interposed therebetween.

In the above, the mold surface is formed by a plurality of separate and independent mold walls 3 for each side (four-wall configuration in the example), but the break ring 5 is formed into an integral ring-shaped configuration, and the joint surface of the two is tapered. Face 6
It is processed into.

However, in this conventional type, as shown in Figure 2,
The edges of each mold wall 3 are configured to press and support each other, and there is a drawback that the internal dimensions of the mold easily change due to temperature changes in the mold wall 3.
In addition, even if the divided mold walls 3 undergo thermal expansion due to temperature changes in practice, they will not be forced into contact with each other, and there will be no gaps due to thermal expansion from the joint between the mold and the break ring 5 made of different materials. Currently, it is only applicable to the size that does not cause the problem, that is, the cross-sectional area is smaller than the size of the slab.

Generally, copper or a copper alloy with good thermal conductivity is used for the walls of this type of mold, and ceramics with good high-temperature strength and spoke ring resistance are used for the break ring, so naturally their coefficients of thermal expansion are different.

(Example) For a slab of 300mm x 300mm Linear expansion coefficient Thermal expansion (mm) Mold 18×10 ^-6 /℃ 1.62/at300℃ (Copper) BR ring 1.0×10 ^-6 /℃ 0.24/at800℃ (BN) BR ring 2.5×10 ^-6 /°C 0.60/at800°C (Si ₃ N ₄ ) However, BR ring: break ring, i.e. 1.38 mm for the combination of copper and BN, copper and Si ₃ N ₄
In combination with this, a gap of 1.02mm will be created.

These gaps cause leakage of molten copper and deterioration of the surface quality of the slab.

(Object of the Invention) The present invention has been made in consideration of the above points, and a mold surface is formed by combining a plurality of divided mold walls, and these mold walls are mutually interconnected by thermal expansion. There is no pressing force or gaps, and even when the break ring is made of different materials and has a different coefficient of thermal expansion, there are no gaps, etc., making it possible to increase the size of the mold. The purpose of the present invention is to provide a high-performance horizontal continuous casting mold that can provide high-quality slabs with no internal dimensional changes and constant slab dimensions.

(Structure of the Invention) Hereinafter, embodiments of the present invention will be described with reference to the drawings.

Fig. 3 is a sectional view of essential parts of a mold in horizontal continuous casting equipment showing an embodiment of the present invention, Fig. 4 is a side view of the mold along line b-b in Fig. 3, and Fig. 5 is a view of the mold wall. The rear view and FIG. 6 are partial cross-sectional views showing another embodiment of the break ring.

In the figure, the same reference numerals are used for parts common to FIGS. 1 and 2.

In this invention, a plurality of mold walls 7 (four-wall configuration in the embodiment) that are separated and independent from the mold surface are used.
It is the same as the conventional type in that it is formed with.

Each mold wall 7 of the present invention is assembled in such a way that one edge surface 8 thereof is in contact with the mold wall surface 9 of the adjacent mold wall 7 near one edge in the longitudinal direction of the mold, and the tundish side end portion 10 is assembled. At the same time, the corner portion of the edge in contact with the adjacent mold wall surface 7 is fixed to the mold frame 11 with a stopper 12, and each mold wall 7 is attached to the mold frame 11 so that it can always slide in close contact with the adjacent mold wall 7.
Each mold wall 7 is configured to be expandable and contractible in the side direction and in the slab drawing direction.

That is, as shown in FIG. 5, one corner of the mold wall 7 at the end 10 on the tundish side is fixed to the mold frame 11 with a fastener 12.
It is designed to be able to expand and contract in the plane direction around this fixed point.

The break ring 13 of the present invention is provided on the mold wall surface 9 for each mold wall 7 along the tundish side end of the mold wall 7.

One end 14 of the break ring 13, that is, the corner end 14 on the corner side where the mold wall 7 is fixed to the mold frame 11, is fixed to the mold wall 7 by a fastener 15, and the other end Part 1
6 is attached with a gap 17 formed between it and the stopper 15 so as to be able to slide in close contact with the mold wall surface 7.

In the figure, 18 is a water cooling jacket attached to the mold frame 11, and 19 is a positioning uneven strip provided on the back side of the mold wall 7 on the joint surface with the water cooling jacket 18, as shown in FIG. They are provided along the tundish side end of the mold wall 7 and the corner side edge fixed by the stopper 12, respectively.

FIG. 6 is a partial cross-sectional view showing another embodiment of the break ring.
A split type break ring 13 is provided at one end of the break ring 13, that is, the mold wall 7.
The break ring end 14 on the edge side, which is fixed to the mold frame 11, is attached to the mold wall 7 with a stopper 15.
and a stopper 15 is attached to the other end.
A gap 17 is formed between the mold wall surface 9 and the mold wall surface 9 so that the mold wall surface 9 can be slid in close contact with the mold wall surface 9.

(Operation and Effect) By having the above-described structure, this invention has the following features:
It has the following effects.

(1) Each mold wall having a split configuration is assembled with each other so that one end surface of the mold wall is in contact with the mold wall surface near one edge of the adjacent mold wall in the longitudinal direction of the mold, and the end surface of the mold wall on the tundish side is In this section, only the corners near the edge of the mold wall on the side that is in contact with the adjacent mold wall surface are fixed to the mold frame using fasteners, and each mold wall is attached to the mold frame so that it can always slide in close contact with each other in the side direction and the slab drawing direction. By attaching the mold wall to
There are no gaps and no dimensional changes inside the mold. Therefore, high-quality slabs can be obtained without changing the cross-sectional area of the cast slab, and there are no dimensional restrictions on the mold wall, making it suitable for large castings. Allows for piece casting.

(2) Each mold wall is fixed to the mold frame with a fastener at only one corner of the end on the tundish side, and the end of the mold wall on the tundish side is fixed to the mold frame with a fastener. Since we provided uneven stripes for positioning along the edge of the corner and the edge of the corner fixed by the stopper, even if it is freely expandable and contractable in the direction of the sides perpendicular to the casting direction, There is no effect of thermal expansion on the tundish side, and the precision of the connection with the tundish nozzle can always be maintained at a high level.Also, when the mold wall wears out, it is easy to attach and detach, making it easy to maintain, and making it possible to change the slab size. It is possible to increase the number of revisions without having to use the same mold, and it is also possible to cast slabs of different sizes using the same mold.

(3) A split break ring is provided on the mold wall surface for each mold wall along the tundish side end of each mode wall, and one end of the break ring, that is, the mold wall is fixed to the mold frame. The end of the break ring on the edge side is fixed to the mold wall with a stopper, and the other end is attached with a gap formed between it and the stopper so that it can slide closely against the mold wall surface. Unlike the break ring, which is a single ring,
It is not necessary to perform tapered surface processing on the mold wall end and the break ring surface, and it is possible to achieve mutual plane joining, thereby increasing joining accuracy, preventing insertion of molten steel and leakage, and extending the life of the mold.

(4) The break ring attached to each mold wall can also be divided into multiple parts and combined, rather than being used as a single unit. The break ring itself can be made of break ring pieces made of different materials, such as one made of a material with high wear resistance, and one made of a material with different linear expansion for adjusting the gap between the combined break rings, and partial replacement is possible. etc. becomes easy.

[Brief explanation of drawings]

Fig. 1 is a cross-sectional view of the main parts of a conventional mold for horizontal continuous casting equipment for casting polygonal slabs, Fig. 2 is a cross-sectional view taken along line a-a in Fig. 1, and Fig. 3 is a cross-sectional view of the mold of the present invention. FIG. 4 is a side view of the mold along line b-b in FIG. 3, FIG. 5 is a rear view of the mold wall, and FIG.
The figure is a partially sectional view showing another embodiment of the break ring. DESCRIPTION OF SYMBOLS 1...Tandate dish, 2...Tandate dish nozzle, 3...Mold wall, 4...Nozzle ring, 5...Break ring, 6...Tapered surface, 7
...Mold wall, 8...Mold edge surface, 9...
Mold wall surface, 10... Mold end, 11...
Mold frame, 12... Stop, 13... Break ring, 14... Break ring end, 15
...Stopper, 16...Break ring end, 17...
...Gap, 18...Water cooling jacket.

Claims (1)

[Claims] 1. In a mold in which the mold surface of horizontal continuous casting equipment for casting polygonal slabs is formed by separate and independent mold walls on each side, each mold wall has one edge in the longitudinal direction of the mold. The end surfaces of the adjacent mold walls are assembled together so as to touch the mold wall surface near one edge of the adjacent mold wall, and the corner portion of the edge side that is in contact with the adjacent mold wall surface is fixed to the mold frame at the end on the tundish side, and Each mold wall is attached to the mold frame so that it can always slide in close contact with the adjacent mold wall, and each mold wall is configured to be expandable and contractible in the side direction and in the slab drawing direction, and the end of the mold wall on the tundish side A divided break ring is provided for each mold wall, and the end of the break ring on the corner side where the mold wall is fixed to the mold frame is fixed to the mold wall, and the other end is tightly attached to the mold wall surface. A horizontal continuous casting mold characterized by being slidably mounted.