DE3544878C2 - - Google Patents

Description

A device according to the preamble of the patent Proverb 1 is known from DE 27 46 238 A1. There are the Ver Ratios in the area of the nozzle selected so that the distance between The nozzle and quenching surface are essentially the same as the Dic ke of the metal strip material to be produced. This means, that the lip of the nozzle that delimits the slot forward in contact with the surface of the solidifying molten metal stands. Furthermore, with the known device, the metal melt applied vertically on the quenching surface, so that the molten metal is also under the rear lip of the nozzle spreads.

It has been shown that with the known Vorrich device produced amorphous metal strip material unsatisfactory surface has surface properties. Especially in manufacturing of strip material with a thickness of about 25 µm or less there is a risk that the tape surface during manufacture becomes rough or scratched.

The invention has for its object a Vorrich tion to indicate that the manufacture of metal strip material with perfect, smooth surface allowed.

The inventive solution to this problem is in the characteristic character part of claim 1 specified. The called in it Measures work together so that only a small part the melt surface when it comes out of contact with the nozzle comes with the lower surface of the nozzle and that this loading contact area at a relatively large distance from the Ab area. Hence the real deterrent process practically without touching the nozzle, and it prevents disturbances caused by on the lips clinging melt plugs or slag.  

The following is a special based on the accompanying drawing preferred embodiment of the invention described in more detail. It shows

Fig. 1 in a partially sectioned side view of the solidification of a metal melt which is extruded from a die onto a roller surface, according to an embodiment of the invention,

Fig. 2 in a cross-sectional view of the imaginary Verfesti a molten metal supply on a roll surface according to DE 27 46 238 A1,

Fig. 3 in a cross-sectional view, the actual Ver consolidation of the molten metal on a Walzenoberflä surface according to DE 27 46 238 A1

Fig. 4 in a somewhat simplified perspective view of the solidification of a molten metal which is ejected onto a roller surface with the device according to the invention and

Fig. 5 is a graphical representation of the surface roughness R _z as a function of the ratio W _F / W of the width W _{F of} the front nose and the slot width W , with curve A showing the experimental result when using a nozzle with a slot a width of 0.63 mm and a rear nose approximately 1.8 mm wide at a distance of 0.13 mm from the quenching surface and curve B the experimental results when using a nozzle with a slot with a width of 0 , 62 mm and a rear nose with a width of about 0.2 mm.

In Fig. 4, the solidification of a molten metal on the quenching surface of a running roller is shown in a perspective view. The speed of movement of the roller surface 45 should be 10 m / s to 50 m / s in order to produce a metal sheet or strip 47 in the amorphous state. The width of the gap or the space between the roller surface 45 and the front nose of the nozzle 41 should be 100 microns to 600 microns. If the width of the gap is less than 100 microns, a small deviation of the roller axis or some slag on the front nose leads to an adverse influence on the surface quality of the metal strip produced, which generally has a thickness of 10 microns to 50 microns.

On the other hand, if the width of the space is over 600 µm, a wave formation occurs on the upper outer surface, i. H. at the Area of the tape that is opposite to the area of the tape with is in contact with the roller surface.  

The ratio W _F / W of the width W _{F of} the front nose to the slot width W is a particularly important influencing factor. In the device described in DE 27 46 238 A1, the front nose has a relatively large width W _F , which fulfills the relationship 1.5 W _F / W 3.0, where W is the slot width of the opening at the end of the slot in the nozzle designated.

In the known device, however, is pressed against the upper outer surface of a metal patch, which is formed between the quenching surface and the front nose, by the lower outer surface of the front nose, which leads to poor quality of the upper outer surface of the metal strip or sheet metal produced . According to the invention, by limiting the width W _{F of} the front nose to W _F / W 0.8, the upper outer surface of the molten metal spot is free and there is an excellent surface finish of the metal strip or metal sheet. The roughness R _{z of} the upper outer surface according to the Japanese industrial standard JIS BO 601-1970 can be improved. Particularly noteworthy is the improvement in the surface quality of relatively thin metal strips with a thickness of 25 µm or less. Since restricting the width such that the relationship W _F / W <0.1 makes the front nose brittle, the width W _{F should have} a value that fills the relationship W _F / W 0.1. Preferably, the slot or channel leading to the nozzle opening is inclined to the quenching surface with respect to the vertical direction, since the freedom of the upper outer surface of the metal patch can be increased. The angle between the direction of movement of the quenching surface and the surface vector of the slot is approximately 10 ° to 70 °, preferably approximately 20 °, in order to achieve a uniform smooth upper outer surface of the metal sheet or strip. If the condition 0.1 W W _F 0.8 W is met, amorphous metal strips with a small surface roughness R _z and without scratches are obtained.

Fig. 1 shows a partially sectioned side view of an embodiment of the device according to the invention. As shown in Fig. 1, a quench surface 8 , which is shown as a surface of a belt or tape, moves in the direction of arrow 9 . A molten metal 4 is discharged from a nozzle or opening 22 which is bounded by a front nose 6, a rear projection 5 and side walls, not shown, to the quench area 8 extruded. The molten metal discharged from the nozzle opening 22 can be distributed in the direction of movement 9 of the quenching surface and is solidified on the quenching surface so that it forms an amorphous strip. The solidified part 7 is shown on the lower part of the tallschmelzflecksens and on the part of the melt which is pulled out of the patch. The rear nose 5 has almost no influence on the molten metal spots 4 .

It can be observed that the front nose 6 can come into contact with the upper outer surface 14 of the molten metal spot 4 by wetting, but hardly exerts any pressure on the molten metal spot. In the present exemplary embodiment, the angle of the surface vector 12 of the slot 2 to the vector of the direction of movement of the quenching surface is approximately 20 °.

The quenching surface moves at a speed of approximately 10 m / s to 50 m / s. In general, the thickness g of the amorphous metal strip produced by this process is in the range from approximately 10 μm to 50 μm. The width of the space G between the front nose and the quenching surface is about 3 to 20 times the thickness g of the tape. It is sufficient that the width W _B of the back of the nose which is 0.1 to 0.8 times the slot width W. The molten metal spot is formed as a drop of melt due to the low viscosity and high surface tension of the melt, and the part of the melt that comes into contact with the quenching surface is solidified into a thin band.

Fig. 2 shows the formation in a partially sectioned side view of a strip of molten metal which is deposited on a moving chill surface from a nozzle in accordance with DE 27 46 238 A1. The rear nose 25 supports the metal melt by means of a pumping action of the melt, which leads to a constant removal of the solidified strip 27 . The hardening front apparently misses the end of the front nose. A mass of molten metal remains above the solidification front. As it is shown in Fig. 2 Darge, the strength of the amorphous metal strip produced is almost equal to the width of the space between the quenching surface and the front nose. The widths W , W _B and W _{F of} the slot 233 , the rear nose and the front nose each measured in the direction of movement of the quenching surface satisfy the relationships 1.5 W _F 3 W and W _B W. In this method, the tabs 25 and 26 press the molten metal patch 24 against the quenching surface to stably obtain a metal band.

As it be in the embodiment in DE 27 46 238 A1 is written, an amorphous metal tape with an alloy composition of Fe₄₀Ni₄₀P₁₄B₆ and a thickness of 0.05 mm from a melt between the noses and the quench surface obtained when the length of the space between the front ren nose and the quenching area is 0.05 mm.

In the known device, a nozzle with a wide front nose, a wide rear nose compared to the slot width of the nozzle opening is used. This process is called the planar casting process. However, studies have shown that the width G of the space between the quench surface 101 and the front nose 96 should preferably be at least 6 times greater than the thickness g of the tape. The length of the space between the front nose and the quench surface is preferably about 0.3 mm if the amorphous metal band has a thickness of 0.05 mm. In this method, there is a gap between the lower surface of the wide front nose and the quenching surface at the point where slag 100 and small metal drops 99 can sit. These slag and metal drops tend to create scratches or defects corresponding to the slag and drops on the upper outer surface of the amorphous metal tape, or otherwise adversely affect the tape surface. Sometimes the drops that enter the space between the roller surface and the nozzle nose cause the nozzle to break in the known method. Due to the uneven height in a direction perpendicular to the direction of movement of the quench surface by slag adhering to the front nose, scratches are produced which run in the longitudinal direction of the band on the upper outer surface of the band. The likelihood of scratching increases noticeably as the strip produced becomes thinner, since the height of the molten metal spot increases compared to the thickness of the strip of metal. It has further been found that the width W _F of the underside of the front nose should be W of the slot in the nozzle measured in the direction of movement of the chill surface is smaller than the slot width, wherein in particular W _F should be to at least 0.8 times smaller than W, to avoid scratches on the upper outer surface of the metal band. In the device described here, no drops occur on the underside of the front nose.

The following are examples of using the above described device described.

example 1

The surface roughness R _{z of} an amorphous metal tape with a width of 20 mm, which was produced with the above device, was measured using the following conditions:
Width of the space between the front nose and the quenching area: 0.13 mm
Angle between the direction vector of the movement of the roller surface and the surface vector of the slot: about 20 °
Width of the slot: 0.63 mm
Width of the rear nose: 1.8 mm

The surface roughness of an amorphous metal strip with a width of 20 mm was measured. The experimental results are shown in Fig. 5 by curve A. As shown in Fig. 5, the surface roughness R _z according to the Japanese industrial standard JIS BO 601-1970 becomes smaller when the ratio W _F / W becomes less than 1.5. The nose width was measured in the direction of movement of the quenching surface.

Example 2

In order to investigate the technical effects of the device described, a further experiment for producing an amorphous metal strip was carried out under the following conditions:
Width of the space between the quenching surface and the front nose: 0.2 mm
Angle between the direction vector of the movement of the roller surface and the surface vector of the slot: about 20 °
Width of the slot: 0.62 mm
Width of the rear nose: 0.2 mm
Front nose width: 0.2 mm

The width of the amorphous metal tape produced in this example was approximately 40 mm. The experimental results are shown by curve B in FIG. 5. Although the roughness R _z is about 3.7 µm when W _F / W is about 2.5, the roughness R _{z is} about 2.7 µm when W _F / W is about 0.35.

Example 3

There were amorphous metal strips under similar conditions prepared as example 2, a device according to DE 27 46 238 A1 was used, where the noses surrounding the slot are measured were relatively wide in the direction of movement of the quenching surface. The workflow was filmed, it turned out has a large amount of slag on the nasal wall stuck and some drops of enamel on the lower surface of the nose sat. In contrast, the one described above results Device no slag formation on the nose wall and it adhere no drops on the lower surface of the nose.

Example 4

A further run was carried out in a similar manner to that of Example 2 made an amorphous metal tape.

The following different experimental conditions were used:
Width of the space between the nozzle lugs and the quenching surface: about 0.3 mm
Thickness of the band: about 18 mm

In this run, amorphous metal strips were made without scratches and created without solidified drops on the upper outer surface. No breaks occurred during casting or after casting the nozzle.

Claims (4)

1. Apparatus for producing amorphous metal strip material with a nozzle ( 1 ) for extruding the molten metal ( 3 ) onto a quenching surface ( 8 ) moving at a speed of 10 to 50 m / s, the nozzle ( 1 ) being one of one in the direction of movement of the quenching surface ( 8 ) has a front lip ( 6 ), a rear lip ( 5 ) and side walls defined rectangular slot ( 22 ) and is arranged at a distance of 100 to 600 microns from the quenching surface ( 8 ), characterized in that that for the production of metal strip material with a thickness g of less than 30 microns measured in the direction of movement of the quenching surface ( 8 ) ne width W of the slot ( 22 ) is between 0.3 and 0.9 mm, the width W _{F of} the front lip ( 6 ) in the ratio W _F / W ≦ 0.8 to the slot width W , the distance G between the front edge of the front lip pe ( 6 ) and the quenching surface ( 8 ) is in the ratio 3 g ≦ G ≦ 20 g to the material thickness g , u nd the feed direction of the molten metal ( 3 ) within the nozzle ( 1 ) forms an acute angle with the direction of movement of the quenching surface ( 8 ). 2. Device according to claim 1, characterized in that the angle between the feed direction of the molten metal ( 3 ) and the direction of movement of the quenching surface ( 8 ) is approximately 70 ° be. 3. Apparatus according to claim 1 or 2, characterized in that 0.1 W ≦ W _F ≦ 0.5 W. 4. Device according to one of claims 1 to 3, characterized in that the measured in the direction of movement of the quenching surface ( 8 ) width W _{B of} the rear lip ( 5 ) according to the Un equation 0.1 W ≦ W _B ≦ 0.8 W. is measured.