JPH021603B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION FIELD OF INDUSTRIAL APPLICATION This invention relates to a method and apparatus for machining a nozzle used for continuous casting of metal, particularly aluminum strip.

BACKGROUND ART Conventionally, one method of manufacturing metal strips such as aluminum is as shown in FIG.
Nozzle 20 is placed between two rotating rolls R ₁ and R ₂
A method is known in which a molten metal M is introduced, cooled and rolled down by rolls R ₁ and R ₂ to form a metal strip S. The nozzle 20 in this case has the shape shown in FIG.

This nozzle 20 is generally made of hardened heat insulating material such as calcium silicate material, ceramic material, etc., and has a roll radius in order to prevent breakout of the molten metal M and backflow of the molten metal between the nozzle and the roll. It is necessary to form a rounded portion 21 with a radius equal to or slightly larger than that of the roll, and to maintain a minute clearance between the roll and the roll. The quality of the metal strip material depends on the processing condition of this rounded portion 21.

Further, the cross-sectional area of the nozzle itself is larger when it is closer to the roll diameter than when it is far away from the roll diameter, and the nozzle itself is not a burr with increased strength, but also has excellent heat insulation properties.

As described above, the machining of the rounded part of a nozzle, which has important technical significance, has conventionally been carried out using a general machine tool by approximating the radius or by machining an arc approximating a polygon. Machines are also being used.

Problems to be solved by the invention All of the above conventional processing methods have poor processing accuracy.
The work is time-consuming and the radius becomes large,
If the width dimension becomes large, it is impossible to process with high precision.

Means for Solving the Problems This invention has been made to solve the above problems, and the first invention is to introduce molten metal M between two rolls R ₁ and R ₂ in continuous casting to When processing the nozzle 20 for continuously manufacturing the trip S, a radiused portion at the edge of both surface areas facing the respective circumferential surfaces of the two rolls R ₁ and R ₂ at the tip of the nozzle 20 is formed. 21, 21 are formed by cutting while a pair of rotary cutting cutters 1, 1 are moved in an arc symmetrically and synchronously with respect to both surface edges of the tip of the nozzle 20. It is the law.

The second invention is an apparatus for processing a nozzle 20 for continuously manufacturing a metal strip S by introducing a molten metal M between two rolls R ₁ and R ₂ in a continuous casting apparatus. , a pair of rotary cutting cutters _1, 1 for cutting and forming rounded portions 21, 21 on the respective opposite surface edges of the two rolls R1, _R2 at the tip of the nozzle 20, The nozzle 20 is pivotally supported via arms 3, 3 on support stands 4, 4 so as to be able to move in an arc so as to be opposite to both surface edges of the tip of the nozzle 20, and the arms 3, 3
Each is connected to a pair of crank plates 12, 12 that are coaxially supported via links 11, 11, and by rotating the pair of crank plates 12, 12, the pair of rotary cutting cutters 1, 1
This is a processing device for a nozzle for a continuous casting machine, characterized in that the nozzle 20 is provided so as to move in a circular arc symmetrically and synchronously with respect to both surface edges of the tip of the nozzle 20.

In the above, the supports 4, 4 for the arms 3, 3
If it is equipped with a mounting position adjustment mechanism so that it can move along the guide rail 9 and adjust the interval of the rotary cutting cutter attached to it, it is useful when processing nozzles of various shapes or when cutting the cutter. This is convenient when the cutter diameter changes after re-polishing.

Function In this invention, cutting is performed by moving a pair of rotary cutting cutters in an arc, so that the cutting surface becomes an arc corresponding to the circumference of the roll, and the arc movement is caused by an arm that pivotally supports the rotary cutting cutters. Since the cutting is performed by a crank body connected via a link, by aligning the starting and ending ends of cutting with the left and right dead centers of the circular motion, the impact on the material due to the circular motion is softened, and the chipping of the material during cutting is prevented. It can be prevented. Furthermore, in the middle part, arcuate motion is added to the rotary cutting, and the cutter moves faster, so cutting time can be shortened.

Embodiments Embodiments of the method and apparatus of the present invention will be described together with reference to the drawings.

FIG. 1 is a front view of an example of the device, and FIG. 2 is a side view of the same.

Reference numerals 1 and 1 designate a pair of vertically opposed rotary cutting cutters, which are rotated by cutter rotation motors 2 and 2, respectively, and constitute a rotary cutting cutter. An arm 3 is attached to the cutter rotation motor 2, and the arm 3 is supported by a support shaft 5 on an arm support base 4 so as to be able to move in an arc.

An adjustment screw 7 rotated by a spur gear 6 is engaged with the arm support 4, and the base end of the arm support 4 is attached to slide on a guide rail 9 attached to a vertical plate 8. be. By operating the handle 10, the spur gear 6 is rotated, and by rotating the adjustment screw 7, the distance between the arm supports 4, 4 is adjusted, and in turn, the distance between the cutters 1, 1 is adjusted. do.

One end of a link 11 is pivotally supported at an appropriate position on the arm 3, and the other end of the link 11 is pivotally supported on a crank plate 12.

The crank plate 12 is driven by a drive shaft 1 that is driven by a motor 13 that rotates a worm gear 17 via a pulley 14, a belt 15, and a pulley 16, and rotates a spur gear 18 that engages with the worm gear 17.
9 and causes the arm 3 to move in an arc via the link 11.

Reference numeral 20 denotes a nozzle to be cut, a second moving table 24 movably fitted onto a guide rail 23 on a fixed table 22, and a first moving table that moves in a direction perpendicular to the second moving table 24 above it. It is held on 25.

Figure 3 shows the rotary cutting cutter part and crank plate 12.
FIG.

4 to 6 are explanatory diagrams of a processing method using the above-mentioned apparatus. In FIG. 4, 20' is a nozzle material, and the first moving table 25 and the second moving table 24 are moved appropriately to Send it in the direction of the arrow while reciprocating in the direction. The cutters 1, 1 are operated by operating the handle 10 as appropriate, and the appropriate adjustment screw 7 is inserted through the spur gear 6.
By rotating the arm support base 4 and sliding the arm support base 4 on the guide rail 9, the spacing thereof is adjusted as appropriate, and the cutter rotation motor 2 rotates the arm support base 4.

At the same time, the power of the motor 13 is transferred to the pulley 14,
belt 15, pulley 16, worm gear 17,
The signal is transmitted to the drive shaft 19 via the spur gear 18 to rotate the crank plate 12, and via the link 11, the arm 3 is swung to perform an arcuate motion. The arm 3 swings vertically in synchronization.

FIG. 5 shows a state in which cutting of the rounded portion has begun, and FIG. 6 shows a state in which cutting of the rounded portion 21 has been completed. This cutting and feeding of the nozzle material are repeated until the desired dimensions are achieved.

Of course, the above processing can be automated. Note that for those with a large nozzle width, the table stroke may be increased.

Effects of the Invention According to the present invention, the edges of both surfaces of the nozzle tip are formed by cutting each of the pair of rotary cutters while making circular arc movements symmetrically and synchronously with respect to both ends of the nozzle tip. Because the rounded part is machined, the cutting surface of the nozzle has a well-balanced and highly accurate arc shape, so when this nozzle is applied to a continuous casting machine, the clearance between it and the roll can be accurately maintained. There is no breakout or backflow of the molten metal, and high-quality casting material can be obtained. Furthermore, since the rounded portions on both surface edges of the nozzle tip are formed by cutting at the same time, there is an advantage that the machining time can be shortened.

Furthermore, in the device, each of the pair of rotary cutting cutters is pivotally supported via an arm on a support base so as to be able to move in an arc so as to face the edges of both surfaces of the nozzle tip. By making circular motion using a pair of supported crank plates, the starting and ending ends of cutting are aligned with the left and right dead centers of the circular motion, which softens the contact with the material caused by the circular motion and prevents the material from chipping during cutting. can do. In the middle of the circular motion, the rotary cutting cutter moves faster, so the machining time becomes shorter.

The rotary cutting cutter is supported by an arm support via an arm, and by changing the spacing between the arms using the arm support mounting position adjustment mechanism, it is possible to respond to changes in the radius of the nozzle. can. Furthermore, even if the cutter diameter changes due to re-sharpening of the cutter, the same rounded part can be processed by changing the arm mounting position.

[Brief explanation of drawings]

FIG. 1 is a front view of one embodiment of the apparatus of the present invention, FIG. 2 is a side view of the same, FIG. 3 is a plan view showing the state of connection between the rotary cutting cutter and the crank plate, and FIGS. FIG. 6 is a front view of the main parts explaining the process order of the processing method, FIG. 7 is a sectional view of the main parts explaining the continuous casting apparatus, and FIG. 8 is a perspective view of the nozzle. 1...Rotary cutting cutter, 2...Cutter rotation motor, 3...Arm, 4...Arm support stand, 5...Spindle, 6...Spur gear, 7...Adjustment screw, 8...Standing plate , 9...guide rail, 10...
Handle, 11...Link, 12...Crank plate, 13...Motor, 14...Pulley, 15
... Belt, 16 ... Pulley, 17 ... Worm gear, 18 ... Spur gear, 19 ... Drive shaft, 20
... Nozzle, 20 ... Nozzle material, 21 ... Round part, 22 ... Fixed table, 23 ... Guide rail, 24 ... Second moving table, 25 ... First
moving table.

Claims (1)

[Claims] 1. In processing a nozzle 20 for continuously manufacturing metal strips S by introducing molten metal M between two rolls R ₁ and R ₂ in continuous casting,
The two rolls R ₁ at the tip of the nozzle 20,
A pair of rotary cutting cutters 1, 1 are symmetrically and synchronously formed with respect to both surface edges of the tip of the nozzle 20 to form rounded portions 21 _, 21 on both surface edges opposite to each other. A method of processing a nozzle for a continuous casting machine, which is characterized by cutting and forming while making an arc motion. 2 Two rolls R ₁ and R ₂ in continuous casting equipment
This is an apparatus for processing a nozzle 20 for continuously manufacturing metal strips S by introducing molten metal M between the two.
Rounded portions ₂₁ , 21 at the edges of both surfaces opposite to the circumferential surfaces of the respective rolls R 1 and R ₂
A pair of rotary cutting cutters 1, 1 for cutting and forming
is rotatably supported via arms 3, 3 on support stands 4, 4 so as to be able to move in an arc so as to be opposite to both surface edges of the tip of the nozzle 20, and the arms 3, 3 each have links 11, 11. By rotating the pair of crank plates 12, 12, the pair of rotary cutting cutters 1, 1 are connected to the tip of the nozzle 20. A processing device for a nozzle for a continuous casting machine, characterized in that the nozzle is provided so as to move in an arc symmetrically and synchronously with respect to both surface edges of the nozzle. 3. For a continuous casting machine according to claim 2, the support stands 4, 4 of the arms 3, 3 are provided with a mounting position adjustment mechanism so as to adjust the distance between the pair of opposing rotary cutting cutters 1, 1. Nozzle processing equipment.