JPS63264252A - Side dam device for belt type continuous casting machine - Google Patents

Abstract

PURPOSE:To hold side dam blocks so as not to incline and to always surely enable the blocks to be close contacted side by side by providing construction having two point supports by each two pins and guide roller arranged to each block in each side dam block. CONSTITUTION:One pair of shifting type side dams 9 held by one pair of water cooled belts 3 at cast slab side, is formed by alternately linking many side dam block 9a having each guide roller 9d and many aide dam blocks 9b having each slender hole 9e. The side dam block 9b is respectively connected with a pin 9c for the adjacent side dam block 9a at one end thereof and connected with the pin 9c for the other adjacent side dam block 9a at the other end thereof, and has the slender hole 9e having the prescribed gap to the linking direction. By this method, the link chain state blocks 9a, 9b are guided on one pair of fixed guide beam 10 by guide rollers 9d while connecting the blocks side by side. Therefore, even if an outer force enforcing the block to incline is worked, as the block is supported at the two points, the outer force is canceled and the inclination is prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a side dam device applied to a belt type continuous casting machine.

[Conventional technology]

The conventional belt type continuous casting fM is shown in Fig. 5, Fig. 6 which is a cross-sectional view taken along the line 5, and Fig. 7 which is a cross-sectional view taken along the If/-1it line in Fig. 6. In the construction, a pair of water-cooled belts 3 are arranged side by side with a gap corresponding to the thickness τ of the slab 21, and a bearing box 5 around which the belts 3 are wound is movable up and down.
The main components include a tension pulley 1 supported by a tension pulley 1, a drive pulley 2 supported by a fixed bearing box 6, and a pair of movable side dams 7 held between both belts 3.

Each side dam 7 consists of a large number of side dam blocks 7 connected by a continuous flexible gold block 7b, each having one guide roller 7cjj, and a pair of fixed guide beams 8 with guide rollers. Contract information will be provided at 7C.

The water-cooled belt 3 and the side door b7VC are each provided with a cooling device (not shown) to cool the solidification heat absorbed from the molten metal 20. In addition, 2 in the figure
0a shows a scene of molten metal 20.

A tension device such as an air cylinder (not shown) for pulling upward in the drawing is attached to the tension googly 1 via a bearing box 5t, and a drive device (not shown) is attached to the drive pulley 2.

When both water-cooling belts 3 are rotated in the direction shown by the arrows via the drive pulley 2 by the drive device (not shown), the clamping force of the water-cooling belts 3 causes both side dams 7 to
moves in the direction shown by the arrow, and continuously supplies molten gold M2O1 to the mold section consisting of the water cooling belt 3 and side dam 7.

The molten metal 20 is cooled and solidified by the water-cooled belt 3 and the side dam 7, which move downward in the figure at an appropriate speed, and the slab 21 moves downward in the figure as indicated by the arrow at a speed equal to the rotational speed y of the water-cooled belt 3. It is discharged and sent to the next process.

[Problems to be Solved by the Invention] Since there is only one guide roller 7C in each of the side dam blocks 7&, as shown in FIG.
Due to the acting forces such as the resistance forces F and F2 received from the metal band 7b, the resistance force F4 received from the belt 3, the resistance force F5 received from the guide beam 8, the posture maintenance is broken and the side dam block A gap was created between 7a, which caused hot water leaks and break-acts to easily occur.

The present invention provides a side dam device for a belt-type continuous casting machine that allows the side dam blocks to be brought into close contact with each other without being tilted even by the above-mentioned acting forces.

This problem can be solved by having a structure in which the nail is supported at two points.

That is, the present invention supplies molten metal to a mold section formed by a pair of water-cooled belts that are arranged parallel to each other and rotate in opposite directions, and a pair of movable side dams that are sandwiched between the water-cooled belts. In the above-mentioned side dam device of a belt-type continuous casting machine that continuously draws out slabs solidified into a shape, a side dam block each having two guide rollers and two pins, and an elongated hole that engages with a pin of the adjacent side dam block. at one end and a side dam block having another elongated hole at the other end that engages with a pin of another adjacent side dam block, which are alternately and continuously connected in the form of a chain link. This invention relates to a side dam device for a type continuous casting machine.

[Effect]

In the present invention, even if an external force acts on the side dam block that tends to tilt the entire side dam block, since the side dam block is supported at two points, all of this external force cancels out and prevents the side dam block from tilting. be able to.

〔Example〕

FIG. 1, and FIG. 2, which is a cross-sectional view taken along the line 1-1 in FIG.
An embodiment of the present invention is shown in FIG. 3, which is an arrow view of the ni gland in FIG. 2, and FIG. 4, which shows some details of FIG. 2. 1st~
In Figure 4, the same members as those in the conventional device are given the same reference numerals and redundant explanations will be omitted.

As shown in FIGS. 1 to 4, a pair of movable side dams 9 are sandwiched between a pair of water-cooled bells 5 and a side dam block 9a having a guide roller 9d and a side dam block 9a having an elongated hole 9ef, respectively. A large number of dam blocks 9b'ji are alternately connected.

Each side dam block 9a is shown in FIGS. 3 and 4 (Al
(As shown in Bl, two pins 9C and the pin 9C
It has two guide rollers 9d mounted on each of the guide rollers 9d.

3 and 4 (Al
(As shown in C1, the pin 901 of the side dam block 9m adjacent to one end of the pin 901!: It has an elongated hole 9ef with a predetermined gap C1 and C2't in the connection direction, and the pin 901 of the side dam block 9m adjacent to the other end is engaged. The pin 9C of another side dam block 9a is engaged with the pin 9C of another side dam block 9a, and a predetermined gap C1 and Q21 are formed in the connection direction.
It has a long hole 90 with f. That is, the Sui-idum book 9b has two elongated holes 9e.

The side dam blocks 9a and 9b connected like a link chain in this way are connected to a pair of fixed guide beams 1.
0 by a guide roller 9d.

Each of the water cooling belt 5 and the side dam 9 is provided with a cooling device (not shown) to completely cool down the solidification heat absorbed from the molten metal 20.

The tension pulley 1 is equipped with a tension device such as an air cylinder (not shown) for pulling upward in the drawing through a bearing box 5, and the drive pulley 2 is equipped with a driving device (not shown).

Drive Goo! by the above drive I & position not shown! 72
When both water-cooling belts 3 are rotated in the direction shown by the arrow through 20 tons of molten metal is continuously supplied to the section.

The molten metal 20 is cooled and solidified by the water-cooled belt 3 and side dam 9, which move downward in the figure at an appropriate speed, and the water-cooled belt 30 rotates at a speed equal to y, forming a piece 21 downward in the figure as indicated by the arrow. It is discharged and sent to the next process.

〔Effect of the invention〕

According to the present invention, the posture of the side dam block can be reliably maintained in a state where it does not tilt even in the casting part,
Since the side dam blocks can always be kept in close contact with each other, stable single-piece production is possible without the occurrence of melting or breakouts, which greatly improves both equipment operating rate and slab yield.

[Brief explanation of drawings]

Is Fig. 1 an embodiment of the present invention? A side view of the belt-type continuous casting machine shown in Figure 2 is the same as Figure 1! Figure 3 is a partial sectional plan view of the Ffr plane located on the - ■ line; Figure 3 is a partial cross-sectional plan view of gland 1-1 in Figure 2;
Fig. 4 (Bl (01 is an explanatory diagram of a part of Fig. 4 (Al), Fig. 5 is a side view of a conventional belt type continuous casting machine, Fig. 6 is a cross section along the line II of Fig. 5) A front view, FIG. 7 is a partial cross-sectional plan view taken along the y-■ line in FIG. 6, and FIG.
This is a partially enlarged front view showing the drawbacks of the conventional case.

Claims (1)

[Claims] Molten metal is supplied to a mold section formed by a pair of water-cooled belts that are arranged parallel to each other and rotate in opposite directions, and a pair of movable side dams that are sandwiched between the water-cooled belts. The side dam device of the belt-type continuous casting machine that continuously draws out solidified slabs includes a side dam block each having two guide rollers and two pins;
A side dam block having one end with a long hole that engages with a pin of the adjacent side dam block and another long hole that engages with a pin of another adjacent side dam block at the other end is arranged in a chain link shape alternately. A side dam device for a belt-type continuous casting machine characterized by continuous connection.