EP0009603A1 - Method and apparatus for the production of metallic strips - Google Patents

Abstract

The invention relates to a method for producing metal strips, in particular from an amorphous metal alloy, wherein a jet of the molten metal from a storage container (15) strikes the rapidly moving surface of a heat sink (11) and solidifies there. The invention further relates to an apparatus for performing this method. To reduce the heat load on the heat sink and to improve the surface quality of the strips produced, the melt jet or reservoir (15) and heat sink (11) are additionally moved relative to one another transversely to the direction of the melt jet emerging from the reservoir (15). The speed of the relative movement can advantageously be 1 mm / sec to 30 cm / sec, depending on the bandwidth of the strip produced.

Description

The invention relates to a method for producing metal strips, in particular from an amorphous metal alloy, wherein a jet of the molten metal hits the rapidly moving surface of a heat sink and solidifies there, and a device for carrying out this method.

Methods are known which allow metal strips to be produced directly from the melt. For example, metal strips with an amorphous structure are produced by quenching a corresponding melt so quickly, typically at a cooling rate of about 10 ⁶ ° C./s, that solidification occurs without crystallization. The known cooling surfaces for the jet of the molten metal can be, for example, the inner or outer surface of a rotating roller or an endlessly rotating belt. The thickness of the so obtained

Bands can be, for example, a few hundredths of a millimeter, the width a few millimeters (see, for example, US Pat. No. 905,758, DE-OS 26 06 581, DE-OS 27 19 710 and DE-OS 27 46 238).

It has now been found that in the production of such metal strips, particularly in continuous operation, the thermal load on the cooling surface due to the impact of large amounts of the molten metal on the same circumferential line is a major problem. This is because there is a risk that the surface temperature of the heat sink increases, which in turn reduces the cooling rate of the molten metal. This can lead to embrittlement of the tape, which can lead to breakage.

Appropriate water cooling can be provided inside the heat sink for faster heat dissipation. But this is relatively expensive.

Furthermore, in the known devices, an increasing waviness of the heat sink surface occurs after a short operating time, which is noticeable as a surface irregularity, such as depressions and increased roughness, on the belt surface.

The invention has for its object to reduce the thermal loading of the heat sink in a method of the type mentioned. At the same time, the surface quality of the strips produced is to be improved and premature breaking due to embrittlement is to be avoided.

According to the invention, this is achieved in that the melt jet and heat sink are additionally moved relative to one another transversely to the direction of the melt jet.

A device for carrying out the method according to the invention with a heat sink, the surface of which rotates around at least one axis, and a storage container for the melt-nosed metal alloy can be designed accordingly in such a way that the storage container and heat sink can be displaced relative to one another transversely to the direction of the melt jet emerging from the storage container.

It has been shown that the method and the associated device according to the invention advantageously significantly reduce the heat load on the heat sink during continuous operation, since the jet of the molten metal repeatedly hits a new circumferential line of the heat sink within the time for critical heating .

It has proven to be particularly favorable if the heat sink is arranged in a fixed manner and the melting jet is moved. For the continuous production of metal strips, it is also advantageous if the speed of the relative movement is low compared to the surface speed of the heat sink. The heat sink is preferably a rapidly rotating cooling roller, since it is particularly easy to handle and has a relatively large mass. In the case of prolonged operation, it may be advantageous to provide additional cooling of the cooling roll. To do this, it is sufficient to direct an inert gas or air flow against the surface of the rotating cooling roll.

Furthermore, it is advantageous if the cooling roller preferably consists of this material because of the high thermal conductivity of pure copper. In principle, however, the cooling roller can also consist of any other material with a relatively high thermal conductivity, such as copper-beryllium or steel alloys.

Typical speeds for the longitudinal movement of the cooling surface of a cooling roll are generally in the range from about 10 to 60 m / s. However, a lower speed of the heat sink is generally sufficient for the production of metal strips with a polycrystalline structure.

The preferred speed of the relative movement between the melt jet and the cooling roll depends on the width of the metal strip produced. A speed in the range between 1 mm / s and 5 cm / s is particularly suitable for narrow strips, for example up to a maximum width of 10 mm, while speeds of 5 cm / s to 30 cm / s can be used particularly advantageously with wider strips . If, on the other hand, one works in the production of very narrow strips with a relative movement speed in the range of 5 to 30 cm / s, there is a danger that the strips will be curved like a saber. In general, the relative speed is therefore preferably at least two orders of magnitude lower than the surface speed of the heat sink.

So that the molten jet can repeatedly drive over as large a surface area of the moving heat sink as possible, especially with larger amounts of melt, it is also advantageous if means are provided for periodically changing the direction of the relative movement. For example Correspondingly arranged electrical contacts when the melt jet approaches an area end. ensure the reversal of the direction of movement. The maximum range for the relative movement of the melt jet transverse to its direction of flow is limited by the width of the heat sink surface. However, it will generally be chosen to be somewhat smaller.

The method according to the invention can be carried out in a manner known per se in air, in an inert atmosphere, for example nitrogen or argon, or under vacuum. In particular when using a vacuum, an improved uniformity of the metal strip produced can be achieved because the oxidizing attack of the atmospheric oxygen is switched off. The device can therefore advantageously have a vacuum chamber in which the reservoir for the melt and the heat sink are arranged.

The invention is to be explained in more detail with reference to a figure which schematically represents an embodiment of the device according to the invention and with the aid of an embodiment.

In the device shown in the figure, the storage container 15 containing the molten metal and the moving cooling roller 11 are arranged in a vacuum chamber 10 which is connected to a vacuum pump by a feed, not shown. The cooling roller 11 is driven via a shaft 12 by an electric motor 14 with speed control located outside the vacuum chamber. A corresponding rotary leadthrough into the interior of the vacuum chamber is designated by 13. The storage container 15, which is surrounded by an induction heating winding 16, is mounted on a subframe 17, which is located on guide rails 18 transversely to the longitudinal can move direction of the storage container. The subframe 17 is driven via a drive spindle 19 by an electric motor 20 which is also located outside the vacuum chamber 10. When one of the contacts 21 is touched, the respective direction of movement of the subframe can be reversed, contacts 22 triggering a change in the direction of rotation of the electric motor 20. The melt jet of the liquid metal can exit through an opening 23, for example a nozzle, at the lower end of the storage container 15 and then strike the surface of the rotating cooling roller 11, where it solidifies to form a continuous belt.

To produce a metal strip with an amorphous structure, an alloy of the composition Fe ₄₀ Ni ₄₀ P ₁₄ B _{6 was} used, the melting temperature of which is approximately 950 ° C. and the crystallization temperature of approximately 360 ° C. The melt in the quartz storage container was heated to about 1000 ° C. by an induction heating coil and then pressed through a nozzle. The molten jet of this alloy hit the surface of a rapidly rotating chill roll made of oxygen-free copper, where it solidified into a solid band. The longitudinal speed of the cooling roll surface was set at about 30 m / s. During the outflow, the molten jet was moved transversely to its outflow direction. The maximum deflection of this movement, the direction of which could be reversed by contacts at the area boundaries, was approximately 15 cm. The speed of the melt jet moving relative to the rotating cooling roll was set at 15 cm / s. The amorphous metal strip produced by the described method was 5 mm wide and had a uniform surface without any ripple.

Further tests showed that saber-like curvatures of the ligaments occasionally occurred. The relative movement was then reduced from 15 cm / s to 1 cm / s. The 5 mm wide strips produced in this way no longer had saber-like curvatures. Further tests have shown that higher, relative speeds are favorable in the production of wider metal strips.

As a rule, one can assume that the width of the metal strip to be produced should be covered in about 0.2 to 1 s by the relative movement of the melt jet to the heat sink. For example, speeds of the relative movement of 1 to 5 mm / s are advantageous for bands of 1 mm width and speeds of the relative movement of between 1 and 5 cm / s are advantageous for bands of 10 mm width.

The method and the device according to the invention are particularly suitable for metal alloys which, after rapid cooling from the melt, have an amorphous structure. Since these alloys are metastable, a reduced cooling rate due to increasing heating of the surface of the heat sink to a temperature near or above the so-called critical crystallization temperature inevitably leads to the embrittlement of the strips. In addition, the method according to the invention and the associated device can also be applied to polycrystalline metal alloys if the advantage of strip production directly from the melt is also important.

The device according to the invention can also be modified in a manner known per se by using the inside of a rotating roller, two counter-rotating rollers or an endlessly rotating belt as the heat sink.

Claims (13)

1. A process for the production of metal strips, in particular made of an amorphous metal alloy, wherein a jet of the molten metal from a reservoir hits the rapidly moving surface of a heat sink and solidifies there, characterized in that the melt jet and the heat sink additionally relative to one another transversely to the direction of the melt jet be moved. 2. The method according to claim 1, characterized in that the relative movement periodically changes its direction. 3. The method according to any one of claims 1 or 2, characterized in that the melt jet is moved. 4. The method according to any one of claims 1 to 3, characterized in that the speed of the relative movement is small compared to the surface speed of the heat sink. 5. The method according to any one of claims 1 to 4, characterized in that the width of the metal strip to be produced is covered in about 0.2 to 1 s by the relative movement of the melt jet to the heat sink. 6. The method according to claim 5, characterized in that the speed of the relative movement between 1 mm / s and 5 cm / s is selected. 7. The method according to claim 5, characterized in that the speed of the relative movement is 5 to 30 cm / s. 8. Device for performing the method according to one of claims 1 to 7 with a heat sink, the surface of which rotates around at least one axis, and a reservoir for the molten metal alloy, characterized in that the reservoir (15) and the heat sink (11) are transverse to each other are displaceable to the direction of the melt jet emerging from the reservoir (15). 9. The device according to claim 8, characterized in that the storage container (15) relative to the fixed heat sink (11) is displaceable. 10. Device according to one of claims 8 or 9, characterized in that a roller is provided as the heat sink (11). 11. The device according to claim 10, characterized in that the cooling roller consists of highly thermally conductive copper. 12. Device according to one of claims 8 to 11, characterized in that the direction of the relative movement can be changed periodically. 13. Device according to one of claims 8 to 12, characterized in that the storage container (15) and heat sink (11) are arranged in a vacuum chamber (10).

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