AT520637A4 - METHOD FOR IMPROVING THE COATABILITY OF A METAL STRIP - Google Patents

Abstract

The subject of this invention is a method for treating a metal strip (1). In this case, the metal strip (1) is heat-treated in an oven (2) and subsequently coated in a coating installation (3). According to the invention, after the heat treatment and before the coating, surface oxides on the metal strip (1) are removed by means of a laser (5).

Description

Summary

The subject of this invention is a method for treating a metal strip (1). The metal strip (1) is heat-treated in an oven (2) and subsequently coated in a coating system (3). According to the invention, surface oxides on the metal strip (1) are removed with the aid of a laser (5) after the heat treatment and before the coating.

(Fig. 1)

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METHOD FOR IMPROVING THE COATABILITY OF A METAL STRIP

The subject of this invention is a method for treating a metal strip. The metal strip is heat-treated in an oven and then coated in a coating system.

High-strength steel grades such as dual-phase steel (DP steel), multi-phase steel, complex-phase steel (CP steel), AHSS (Advanced High Strength Steels) or UHSS (Ultra High Strength Steels) combine high strength with optimized formability. These steels are mainly used as sheet metal in the automotive industry. They enable a reduced weight and greater freedom in design for various structural reinforcements and crash components.

All steels whose structure consists of a ferritic (soft) matrix, in which a predominantly martensitic (strength-enhancing) second phase is island-shaped at the grain boundaries are referred to as dual-phase steel (DP steel). This structure has a relatively low yield strength, which is favorable for the forming process, and high tensile strength. These properties are advantageous for complex deep-drawn parts.

Advanced High Strength Steel describes modern high-strength steel grades that belong to the cold work steels. They are also called carbon steel, carbon steel, carbon steel and AHS steel in the trade.

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To ensure that these high-strength steels are adequately protected against corrosion, they are coated. For example, they are coated with a zinc layer or a zinc alloy in a metal bath. In newer processes, these tapes are also vacuum-coated with a metal layer (Jet Vapor Deposition (JVD)). Before coating, these steels, which are generally cold-rolled, are subjected to a heat treatment to change their structure, preferably in an annealing furnace.

These high-strength steels usually contain a high proportion of alloying elements such as silicon (Si), manganese (Mn) or aluminum (Al), sometimes also chromium (Cr) or phosphorus (P). Some of these special steels can also contain molybdenum (Mo), niobium (Nb), titanium (Ti) or boron (B).

These alloying elements form surface oxides such as Si02, MnCU, MnSiO3, Mn2SiO4, AI2O3, Cr2O3 etc. on the strip surface during the heat treatment. The thickness of this oxide layer is very thin and is usually in the nanometer range (200 to 500 nm). These oxide layers are therefore considerably thinner than conventional scale layers (iron oxide), which are in the range of 7 to 10 μm.

Nevertheless, these metal oxides on the strip surface have a very negative effect on the coatability of the metal strips. The metal oxides, for example, significantly reduce the wettability for zinc, which can lead to problems with hot-dip galvanizing.

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There are already several approaches in the prior art which are intended to prevent the formation of these metal oxides on the strip surface, for example by a strongly reducing atmosphere in the annealing furnace. However, even the smallest amounts of oxygen or water lead to the formation of these oxides.

EP 1 829 983 B1 tries to solve the problem with a furnace with a non-oxidizing zone, an oxidizing zone and a reducing zone, the air / fuel ratio in the directly fired zone having to meet certain requirements.

In another approach, the annealed metal strip is pickled so that the oxides of the alloying elements are removed by the acid. After that, however, the metal strip must be reheated again to have the right temperature for the zinc bath. This process is therefore complex and expensive, and the oxides of the alloying elements are generally more difficult to remove than iron oxide.

In a further approach, a thin iron layer is applied electrolytically to the metal strip before the heat treatment (Fe flash layer). It has been shown that this iron layer reduces the formation of Mn, Al and Si oxides on the strip surface. However, this does not work satisfactorily with all high-strength steels. It is also known to electrolytically apply a thin layer of nickel (nickel flash), which then at least partially serves as a diffusion barrier for the alloy elements.

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EP 2 956 296 B1 describes a method in which two separating layers are applied in succession to the metal strip before the heat treatment, namely first a copper layer and then an iron layer. However, this process is quite complex.

EP 2 631 319 A1 attempts to get the wetting problem in hot-dip galvanizing under control by adding a defined amount of aluminum to the zinc bath and by means of precisely defined temperature windows.

The invention is therefore also based on the object of providing a method in which heat-treated metal strips, which preferably contain alloying elements such as Si, Mn, and Al, can be reliably coated; this is preferably a metallic coating, for example a zinc layer or can be coated around an aluminum layer. It can be a zinc layer with a low aluminum content (Galfan), a zinc layer with a higher aluminum content (Galvalume) or a zinc layer with manganese or with Al / Si additives.

This object is achieved by a method according to claim 1.

According to the invention, surface oxides on the metal strip are removed using at least one laser after the heat treatment and before the coating. The thin oxide layer is evaporated or caused to flake off by the laser beam. This enables the subsequent coating to be carried out without any problems.

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The present invention is particularly suitable for the treatment of cold-rolled, heat-treated high-strength steel strips which contain elements, such as silicon, manganese or aluminum, which diffuse to the surface during the heat treatment and form various oxides there due to the residual oxygen content of the furnace atmosphere. These oxides are then very difficult or difficult to remove in the normal reducing atmosphere.

Current metal strips, which are particularly affected by the coating problems caused by surface oxides, contain the following alloying elements:

Si: 0.5 - 2.5%

Mn: 0.5 - 2.5%

Al: 0.5-1.5%

Cr: 0.2 - <1%

Mon: <1%

Future steel grades can also have silicon, manganese and aluminum contents of up to 5%. There are also special steels with a very high manganese content of 30 50%.

It is also conceivable that the coating is a passivation layer as corrosion protection. These passivation layers are often applied to aluminum strips or aluminum alloys, they serve as corrosion protection, but also improve the adhesion of paints, adhesives and powder coatings. For example, surface oxides of

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Aluminum strips are removed after the heat treatment and before passivation with a laser.

The metal strip is preferably continuously heat-treated in an oven.

It is advantageous if the furnace has a heating section and a subsequent cooling section and if the surface oxides in the cooling section are removed. Continuous furnaces often have two strip tension rollers at the end of the cooling section, which ensure a corresponding strip tension in the furnace. The laser treatment can preferably take place in the area of these tape tension rollers, ideally on both sides, since the tape travel is very stable there.

It is advantageous if the metal strip is immersed and coated directly after the furnace in a metal bath, for example in a zinc bath (optionally with alloy additives such as aluminum).

However, it is also conceivable for the metal strip to be coated in a coating system by depositing metal vapor (jet vapor deposition) or for it to be coated electrolytically. The invention does not require that the metal strip must be coated immediately after the heat treatment. The metal strip can also be stored temporarily. It is only essential that between the heat treatment process and the coating process, surface cleaning is carried out with the aid of at least one laser, in order to remove the oxides formed on the metal strip surface during the heat treatment.

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Ideally, the surface oxides on both sides of the strip are removed by the laser beam or beams.

It is advantageous if the removed surface oxides are suctioned off immediately after they have been released. The surface oxides can be in vapor form or as fine particles.

It is to be expected that the oxides do not cover the entire metal strip surface, but are only present in regions, for example as spots. In this regard, it is favorable to scan the metal surface with a scanner and to identify the areas covered with oxide. The laser treatment then only takes place in these areas.

Several exemplary embodiments of the invention are described below with reference to drawings.

Figures 1 to 3 show three possible embodiments of the method according to the invention in a hot-dip galvanizing line.

Figures 4 and 5 show two exemplary embodiments of a system in which the metal strip is coated with metal vapor in a vacuum.

The same reference numerals in the figures denote the same parts of the system.

FIG. 1 shows a hot-dip galvanizing plant in which a metal strip 1 is first heat-treated continuously in an oven 2 and then in a coating plant 3

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3361 AT is coated. The heat treatment in the furnace 2 is necessary in order to anneal the metal strip 1, which has become hard as a result of the previous cold rolling step, and to define the desired properties of the metal strip 1 by appropriate annealing and cooling cycles. In the furnace 2, the metal strip 1 is passed over various deflection rollers 10.

The heated section 9 of the furnace 2 can either be fired directly (DFF, direct fired furnace) or indirectly heated via radiant tubes (RTF, radiant tube furnace), induction heating is also conceivable. As a rule, several of these heating concepts are combined in one oven 2.

In the cooling section 8 of the furnace 2, the metal strip 1 is cooled, for example, with hydrogen. The necessary strip tension in the furnace 2 is generated by the two strip tension rollers 6 at the end of the cooling section 8. Following the furnace 2, the metal strip 1 dips into the zinc bath 7 in a manner known per se via the trunk 11 and is galvanized there.

The lasers 5 are located in the area of the two strip tension rollers 6. The laser beams are directed onto the respective metal strip surface pointing away from the strip tension roller 6.

The lasers 5 can be, for example, an Nd: YAG, a CO2 or a diode laser.

The oxides formed during the heat treatment are removed by the lasers 5 and extracted by the suction 13. Depending on the laser power, the oxides are evaporated or they chip off the metal strip surface.

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Several lasers 5 can be arranged alongside one another over the bandwidth, so that the entire bandwidth can be treated simultaneously. It is also possible for one or more laser beams to scan the strip surface in a line (transverse to the strip running direction). The lasers 5 can also be arranged outside the furnace 2, the laser beams are then guided into the furnace interior through special optical waveguides or special glass windows.

The two belt surfaces are continuously scanned by scanner 12 and the surface areas on which the oxides are located are thus identified. It is conceivable that the oxides do not cover the entire surface of the metal strip surface. The laser beams are then controlled so that only the areas covered with oxide are cleaned or treated.

Of course, it is also conceivable that the entire strip surface is always treated with the laser or lasers.

FIG. 2 shows a system similar to that of FIG. 1, only here the scanners 12, the lasers 5 and the suction 13 in the cooling section 8 are already arranged in front of the tape drawing rollers 6.

In Figure 3, the scanner 12, the laser 5 and the suction 13 are arranged in the trunk 11 of the coating system 3.

FIG. 4 shows a further system 4 for coating a metal strip 1. After the heat treatment 14, this happens

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Metal strip 1 first a lock system 15 made up of several rollers 16. Here, the pressure is gradually reduced because the coating is carried out in a vacuum or in the case of a vacuum. This is followed by a brief warm-up via heating elements 17 and then coating in the vacuum chamber 18. During the coating process, vaporous zinc is deposited on the metal strip 1 via nozzles 19. The coating method is known in specialist circles under the term “jet vapor deposition. The pressure is then built up again via a second lock system 20.

Immediately before coating in the vacuum chamber 18, i.e. after heating by the heating elements 17, the oxide is removed with the aid of lasers 5. In FIG. 4, the laser beams and the suction 13 are directed onto the deflection rollers 21.

In FIG. 5, the laser 5 and the suction 13 are located between the two deflection rollers 21.

Here too, the surface areas covered with oxide can be identified by a scanner 12 and the lasers 5 can be controlled accordingly.

The laser cleaning according to the invention after the heat treatment can also take place in front of an electro-galvanic coating system (EGL).

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Claims (13)

claims 1. A method for treating a metal strip (1), the metal strip (1) being heat-treated in an oven (2) and subsequently coated in a coating system (3, 4), characterized in that after the heat treatment and before the coating, surface oxides on Metal strip (1) can be removed with the help of at least one laser (5). 2. The method according to claim 1, characterized in that the metal strip (1) in the coating system (3, 4) is coated with a metallic coating. 3. The method according to claim 1 or 2, characterized in that the metal strip (1) is continuously heat-treated in an oven (2). 4. The method according to claim 3, characterized in that the furnace (2) has a heating section (9) and a subsequent cooling section (8) and that the surface oxides in the cooling section (8) are removed. 5. The method according to claim 3 or 4, characterized in that the metal strip (1) is immersed in a metal bath (7) directly after the furnace (2) and is coated there. 6. The method according to claim 5, characterized in that the metal strip (1) in the metal bath (7) is galvanized. 7. The method according to any one of claims 1 to 4, characterized in that the metal strip (1) in the 12/20 3361 AT Coating system (4) is coated by the deposition of metal vapor. 8. The method according to any one of claims 1 to 4, characterized in that the metal strip (1) is electrolytically coated in the coating system. 9. The method according to any one of claims 1 to 8, characterized in that the surface oxides on both sides of the strip are removed by laser (5). 10. The method according to any one of claims 1 to 9, characterized in that the removed surface oxides are suctioned off. 11. The method according to any one of claims 1 to 10, characterized in that the metal strip surface is scanned with a scanner (12) so as to identify the areas in which the surface oxides are located, and that only these areas with the laser (5th ) be treated. 12. Application of the method according to one of claims 1 to 11, characterized in that it is used to treat a metal strip (1) which also contains the alloying elements Si, Mn and Al. 13/20