JPS63174720A - Method and device for winding nonmagnetic rapid cooling metal - Google Patents

Abstract

PURPOSE:To surely catch a rapid cooling metal having no magnetism and to start the winding by feeding a magnetic dummy sheet to a transferred rapid cooling metal and starting the winding by pinching it between a winding reel and the magnetic dummy sheet. CONSTITUTION:When a 2nd circulating belt 5 is returned to the position of a continuous line simultaneously with cutting rapid cooling metal by a rapid cooling metal cutting means 12 at the time of completing the scrapping to a scrap box 11 of the part having many qualitative defects at the initial casting time, the rapid cooling metal 1 travels on a 2nd circulating belt 5 on the same level as that of a 1st circulating belt 4. When a dummy sheet 10 is cut off by a cutting means 13 at the time when the rapid cooling metal reaches the center of a 3rd circulating belt 6, the tip vicinity of the rapid cooling metal is covered by the dummy sheet 10. The rapid cooling metal covered by the dummy sheet 10 is transferred on the 3rd circulation belt 6 and when it reaches on the winding reel 7 burying a permanent magnet, the rapid cooling metal is pinched by the magnetic force between the dummy sheet 10 and reel 7 to start the winding.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a method and apparatus for winding rapidly cooled cast metal without magnetism.

[Conventional technology]

Conventionally, a method has been proposed as a method for winding quenched metal. For example, in JP-A-55-70414 and JP-A-57'-9'4453,
A method has been proposed in which quenched metal is directly wound up by magnetic force using a take-up reel having a magnet. However, the method of winding by magnetic force could not be applied to rapidly solidified metals that do not have magnetism.

[Problem that the invention seeks to solve]

SUMMARY OF THE INVENTION In order to solve the problems of the conventional method of directly winding quenched metal with magnetic rolls, the present invention provides a winding method that can be applied to quenched metal that is not magnetic.

A further object of the present invention is to provide a winding device that can continuously wind a non-magnetic metal over a long period of time, or can immediately respond to breakage of rapidly cooled metal.

[Means and effects for solving the problem] The present invention winds up a magnetic dummy sheet onto a magnetic take-up reel and at the same time inserts rapidly cooled metal transported by a circulating belt. It is characterized by the start of winding, and the gist is that in the method of winding up non-magnetic quenched cast metal, the process begins near a cylindrical take-up reel that has a magnetic force on the surface and rotates at the same peripheral speed as the quenched metal. , a magnetic dummy sheet is supplied from above to the quenched metal transported by the circulation belt, and the dummy sheet is wound onto the take-up reel while covering the surface near the tip of the quenched metal. It is characterized in that the metal is sandwiched between the winding reel and the dummy sheet and winding is started.

Furthermore, the present invention arranges three or more circulating healds in series between a carrousel type continuous winding device having a winding reel with magnetic force on its surface and a roll for quenched metal casting. At least one of the circulation belts other than the belt is provided so as to be tiltable so that the take-up reel side is at a lower position, and a quenching metal cutting device is arranged near the end of the circulation belt on the casting roll side. .

That is, defective quenched metal parts at the initial stage of casting or at the beginning of restarting casting after rupture of quenched metal are cut by a cutting device while the winding reel side of the tiltable circulation belt is lowered and the LB is fed. After that, the tiltable circulation belt is returned to its normal position, and the magnetic dummy sheet is supplied from above the VA ring belt closest to the take-up reel by transporting the cold metal. Start winding.

When the winding amount reaches a predetermined value of 1, the rapidly cooled metal is cut by the cutting device described above. On the other hand, the subsequent quenched metal continues to be conveyed by the circulation belt, and the dummy sheet is supplied in the same way as above and wound onto other waiting take-up reels. Continuous winding is performed.

The present invention will be explained below with reference to the drawings.

FIG. 1 shows an example of a rapidly solidified metal manufacturing apparatus for carrying out the present invention.

In the figure, a circulation heald 4.5.6 is arranged in series between the casting roll 2 and a carrousel continuous winding device 16 provided with a magnetic take-up reel 7.8, and a third WI ring near the take-up reel 7 A magnetic dummy sheet supply coil 9 is provided above the belt 6, and a dummy sheet cutting machine 13 is disposed adjacent to and below the supply coil 9.

The second circulation belt 5 is tiltable around the belt drive unit 14 so that the take-up reel side can descend as shown by an arrow, and near the end of the tiltable circulation belt on the casting roll 2 side A quenched metal cutting machine 12 is provided.

In this example, the second W1 ring belt is arranged so as to be tiltable, but the first W1 ring belt is arranged so as to be tiltable. The fl ring belt 4 may be made tiltable, and among the plurality of circulation belts arranged, one of the circulation belts except the one closest to the take-up reel may be made tiltable, and the casting roll A quenched metal cutting machine may be provided near the side end.

2. In the method of the present invention using such an apparatus. A method for winding cold metal will be explained.

Before starting casting, the drive-roll 15 side of the second circulation belt 5 is lowered in the direction of the arrow with the roll 14 as the rotation axis, as shown by the broken line. Rotating the casting roll 2 at a predetermined speed,
Although the location is not specified, molten metal 3 is supplied onto casting rolls 2, and quenched metal is cast. Suddenly, the cold metal 1 is peeled off from the casting roll 2 by a well-known method, guided, and runs on a first circulation heald 4 and then on a second circulation belt 5 whose position on the winding roll side is lowered as shown by the broken line. However, defects in the initial stage of casting and quenched metal are placed in a scrap box 11.

At this point, the ferromagnetic dummy sheet supply coil 9 is already
The dummy sheet 10 of a predetermined length is unwound to such an extent that it falls onto the third WI ring belt 6.The running speed of each circulation belt is set to be equal to or slightly higher than the casting speed of the rapidly cooled metal, but at least the first The traveling speed of the circulation heald 4 is set to the second
By making the cooling speed slightly faster than that of the circulation heald 5, tension is generated in the rapidly cooled metal between the first circulation belt 4 and the second f&ring belt 5.

Scrap box 11 of parts with many quality defects in the initial stage of casting
At the point when you want to end the waste disposal, run at the same level as the rapid cooling. When the quenched metal reaches the center of the third circulation belt, the dummy sheet 10 is cut off by the cutting means 13, and the vicinity of the tip of the quenched metal is covered with the dummy sheet 10.

That is, when feeding a dummy sheet, the dummy sheet is unwound from the dummy sheet supply coil to the extent that its tip hangs over the circulation bell I, and when the quenched metal arrives, a predetermined length of the dummy sheet is synchronously fed from the coil. Cut and supply the dummy sheet.

When the quenched metal covered with the dummy sheet 1-10 is conveyed through the first circulation belt 4 and reaches the take-up reel 7 in which a permanent magnet is embedded, the quenched metal is pinched by the magnetic force between the dummy sheet 10 and the reel 7. winding begins.

The take-up reel 7 moves from position A to position B, and when it has taken up a predetermined amount, the next reel 7 is kept in standby at position A, and the next reel 7 is then cut in conjunction with the cutting of the rapidly cooled metal by the cutting machine 12. If the dummy sheet 9 is wound by the machine 13, it can be wound on the next reel in the same manner as described above, and continuous winding can be performed for a long time.

If the quenched metal breaks unexpectedly during the period when the unwound reel 7 is kept at position A, a ribbon breakage detection device (not shown) is installed closer to the casting roll than the dummy sheet cutter 13. is provided, and the dummy sheet 10 is removed by the dummy sheet cutting 13 in conjunction with the break signal, thereby making it possible to easily restart the winding.

Also, while the take-up reel 7 is moving from position A to B, the second
If the take-up reel side of the circulation belt is lowered in the direction of the arrow, even if the quenched metal breaks, the metal will be guided to the scrap box after the break. Then, by following the procedure described above after discarding the initially defective part of the casting, it is possible to restart winding.

In addition, when carrying out the present invention, it is preferable to apply tension to the quenched metal in order to ensure that the dummy sheet is overlapped with the quenched metal and to reliably cut the quenched metal at a predetermined position. It has been found that it is most desirable to use a suction-fixed circulation belt to meet the requirements.

Figure 2 shows an example of a suction type circulation belt.

The belt 17 is run by a drive roll 18 and a roll 19. As shown in FIG. 2-B, the belt 17 has
A large number of atmospheric air suction ports 20 are opened in a belt shape, and although not shown, the side surface of the belt is hermetically sealed, and the inside is depressurized. Therefore, the rapidly cooled metal is attracted and fixed to the upper surface of the belt as it travels. In order to reduce suction loss from the lower surface of the belt, a contact plate 21 is provided on the inner surface of the lower surface of the heald.

Note that the width l of the suction hole zone of the circulation belt may be equal to or greater than the casting width of the quenched metal in the first circulation belt 4 and the second Wi ring belt 5 in FIG. If the third circulation belt 6 near the winding reel is made wider than the casting width, and the dummy sheet width is made larger than the casting width, the quenched metal can be reliably held down.

Further, the quenched metal cutting means 12 may be any known method such as slitting from above and below using two blades or punching quenched metal using a bullet.

The same applies to the dummy sheet cutting means 13.

Although the present invention has been mainly described above regarding winding of quenched metal ribbon, it goes without saying that the present invention can be applied to multi-thread ribbons, multi-thread wires, and the like.

C. Effects of the Invention] According to the present invention, it is possible to reliably capture the non-magnetic quenched metal and start winding. Further, according to the present invention, it is possible to immediately respond to the breakage of the rapidly cooled metal, and it is also possible to perform continuous winding for a long time.

[Brief explanation of the drawing]

Fig. 1 is an explanatory diagram of a manufacturing apparatus for rapidly cooled cast metal according to the present invention, Fig. 2 is an example of a suction type circulation belt for conveying rapidly cooled metal according to the present invention, and Fig. 2-A is a side view. Figure, 2nd
Figure-B is a plan view. 1: Quenched metal 2: Casting roll 3 molten metal 4: First circulation belt 5: Second circulation belt 6: 31st ring belt 7: Take-up reel 9:
r1 dummy sheet supply coil 10: dummy sheet 11 scrap box 12: cold metal cutting machine 13: dummy sheet cutting machine 14: helmet %W working section 15: belt drive section 16: continuous winding device 17
: Helt 18: Driving roll 1: Driving roll 20: Atmospheric suction hole 21: Our agent Patent attorney Tatsuo Chanoki Figure 2 (A)

Claims (2)

[Claims] (1) In a method for winding up non-magnetic quenched cast metal, the quenched metal is transported by a circulating belt to the vicinity of a cylindrical take-up reel that is magnetic and rotates at the same peripheral speed as the quenched metal. Supply the magnetic dummy sheet from
A method for winding non-magnetic quenched metal, which comprises sandwiching the quenched metal between the take-up reel and the magnetic dummy sheet and starting winding while covering the surface near the tip of the quenched metal. . (2) At least three circulating belts that are driven independently of each other are arranged in series between the carrousel type continuous winding device equipped with a magnetic take-up reel and the rapidly cooled metal casting roll. One of the two circulation belts is provided so that the take-up reel side can be tilted to a lower position, a quenching metal cutting device is provided near the end of the circulation belt on the casting roll side, and a magnetic dummy sheet is placed above the third circulation belt. A winding device for non-magnetic quenched metal characterized by being equipped with a feeding device and a dummy sheet cutting machine.