EP1672088B2 - Method for manufacturing a body featuring very high mechanical properties, forming by cold drawing from a rolled steel sheet, in particular hot rolled and coated sheet - Google Patents

Description

The invention relates to a method for producing a part with very high mechanical characteristics, shaped by stamping, from a strip of rolled steel sheet and in particular hot rolled and coated with a metal or metal. a metal alloy providing protection of the surface and steel.

The steel sheets to be subjected to high temperature forming and / or a heat treatment are not delivered coated for reasons of resistance of the coating during the heat treatment, the heat treatment of the steels generally being carried out at relatively high temperatures well above 700 ° C. Indeed, a coating of zinc deposited on a metal surface has been considered until now as being able to melt, flow, foul the hot forming tools, during heating, at temperatures above the melting temperature of zinc , and degrade during rapid cooling.
The coating is therefore performed on finished part which requires a careful cleaning of surfaces and hollow parts. This cleaning requires the use of acids and / or bases whose recycling and storage are a significant financial burden and present risks for operators and the environment. In addition, the heat treatment must be carried out under a controlled atmosphere in order to avoid decarburization and oxidation of the steel. Then, in the case of hot forming, calamine, by its abrasive power, damages the forming tools, which reduces the quality of the parts obtained from the dimensional and aesthetic point of view or requires frequent and expensive repairs tools. Finally, to increase their resistance to corrosion, the parts thus obtained must receive an expensive post-processing whose application is difficult or impossible, especially in the case of parts with depressions. The post-coatings of steels with very high mechanical characteristics also have the disadvantage of creating hydrogen embrittlement risks in electro-galvanizing techniques or modifying the mechanical properties of these steels in dip galvanizing techniques. previously formed parts.

The object of the invention is to propose to the users, steel sheets rolled from 0.2 mm to about 4 mm thick, coated in particular after hot rolling, and to undergo a shaping, cold followed by a heat treatment, as well as a process for making part by forming, from these coated steel sheets, the temperature rise being ensured without decarburization of the steel of the sheet, without oxidation of the surface of the sheet; said sheet, before, during and after the heat treatment.

• on découpe la tôle pour l'obtention d'un flan de tôle,
• on effectue un emboutissage à froid, à partir du flan de tôle pour obtenir la pièce,
• on réalise, après emboutissage, par traitement thermique un composé allié intermétallique, en surface, assurant une protection contre la corrosion, et contre la décarburation de l'acier, ledit composé étant obtenu par transformation du revêtement en un alliage intermétallique par une élévation de température supérieure à 700°C,
• la pièce obtenue par emboutissage est refroidie pour subir une trempe, à une vitesse supérieure à la vitesse critique de trempe,
• on retire par découpage, les excédents de tôle nécessaires à l'opération d'emboutissage.

The subject of the invention is a process for producing a part with very high mechanical characteristics, shaped by stamping, from a strip of rolled steel sheet, in particular hot-rolled and coated with zinc or aluminum. a zinc-based alloy providing protection of the surface and steel, characterized in that:

• the sheet is cut to obtain a sheet blank,
• cold stamping is carried out from the sheet blank to obtain the part,
• after stamping, by heat treatment, an intermetallic alloy compound is produced at the surface, providing protection against corrosion, and against decarburization of the steel, said compound being obtained by transforming the coating into an intermetallic alloy by raising the temperature. greater than 700 ° C,
• the part obtained by stamping is cooled to undergo quenching, at a speed greater than the critical quenching speed,
• the excess sheet metal required for the stamping operation is removed by cutting.

• le métal ou l'alliage métallique du revêtement est du zinc ou un alliage à base de zinc d'une épaisseur comprise entre 5 µm et 30 µm.
• l'alliage intermétallique est un composé à base de zinc-fer ou à base de zinc-fer-aluminium.

The other features of the invention are:

• the metal or metal alloy of the coating is zinc or a zinc-based alloy with a thickness of between 5 μm and 30 μm.
• the intermetallic alloy is a compound based on zinc-iron or based on zinc-iron-aluminum.

The invention also relates to the use of a strip of rolled and in particular hot-rolled steel sheet coated with zinc or a zinc-based alloy providing protection of the surface and steel of the sheet metal. in the stamping of parts, the parts having high mechanical properties in hardness and high surface hardness characteristics and a very good resistance to abrasion.

• La figure 1 est un schéma de principe d'un procédé ne faisant pas partie de l'invention.
• La figure 2 est un schéma de principe d'une forme de l'invention.
• Les figures 3a et 3b sont des photographies, en coupe, d'une partie de pièce, présentant un revêtement zinc réalisé selon le procédé de la figure 1, avant et après traitement thermique.
• Les figures 4a et 4b sont des photographies, en coupe, d'une partie de pièce, présentant un revêtement zinc aluminium réalisé selon le procédé de la figure 1, avant et après traitement thermique.

The description which follows and the appended figures will make the invention clear.

• The figure 1 is a block diagram of a process not forming part of the invention.
• The figure 2 is a block diagram of a form of the invention.
• The Figures 3a and 3b are photographs, in section, of a part of a piece, having a zinc coating produced according to the method of figure 1 , before and after heat treatment.
• The Figures 4a and 4b are photographs, in section, of a part of a piece, having a zinc aluminum coating produced according to the method of figure 1 , before and after heat treatment.

The process presented in the diagram of the figure 1 , consists, from a sheet of a steel for heat treatment and hot forming, in particular hot rolled and coated with zinc or a zinc-based alloy, in the production of a hot-formed part in the form of tool means such as a stamping press.

The zinc or zinc alloy coating is selected so as to provide corrosion protection for the base sheet in a coil.

Contrary to popular belief, during a heat treatment or a rise in temperature for hot shaping, the coating forms a layer which combines with the steel of the strip and present at this moment a mechanical strength avoiding the melting of coating metal. The formed compound has high resistance to corrosion, abrasion, wear and fatigue. The coating does not alter the formability properties of the steel and thus allows a wide variety of cold and hot forming.

In addition the use of zinc or a zinc alloy generates a galvanic protection of the slices when the sheet blank or the piece has cutouts.

After hot rolling, the strip can be pickled and cold rolled before being coated. In the case where the sheet is cold rolled, it can be annealed before being coated.

The rolled sheet can be coated, for example, with zinc, or zinc aluminum alloys.

As shown in the diagram of the figure 2 , the sheet is cold stamped to obtain the piece. The resulting part is then subjected to a heat treatment to give it high mechanical characteristics. For example, a base steel having a breaking strength Rm of about 500 MPa will make it possible to obtain heat-treated parts having a steel with a resistance Rm greater than 1500 MPa.

For the heat treatment of the workpiece, the sheet is subjected to a temperature rise preferably between 700 ° C and 1200 ° C in a furnace with an atmosphere no longer requiring control, because of the barrier to oxidation formed by the coating. When raising the temperature, the zinc-based coating is transformed into an alloyed surface layer having different phases depending on the temperature treatment and having a high hardness of more than 600 HV 100g.

In the process of the invention, sheets having a thickness of between 0.2 mm and 4 mm may be used, having good shaping properties as well as good corrosion resistance.

The sheets delivered coated, have a significant resistance to corrosion during temperature rises, shaping, heat treatments, and during the use of finished formed parts.

The presence of the coating during heat treatments makes it possible to avoid, in addition to corrosion, the decarburization of the base steel. In addition, the effect of protection against decarburization of the intermetallic alloy allows the use of high temperature furnace exceeding 900 ° C having an uncontrolled atmosphere, and this, even for heating times of several minutes.

Out of the oven, it is no longer necessary to strip the piece obtained, resulting in a saving due to the removal of the pickling bath of finished parts.

Due to the characteristics of the coating after temperature rise, the parts obtained have an increased resistance to fatigue, wear, abrasion and corrosion, including on the wafer because of the galvanic behavior of the zinc with the steel. In addition, the coating is weldable before and after temperature rise.

The steel of the sheet ensures, by cooling quenching effect, high mechanical characteristics of the part obtained after shaping.

Example 1: zinc coating on steel.

• carbone : 0,15% à 0,25%,
• manganèse : 0,8% à 1,5%,
• silicium : 0,1% à 0,35%,
• chrome : 0,01% à 0,2%,
• titane : moins de 0,1%,
• aluminium : moins de 0,1%,
• phosphore : moins de 0,05%,
• soufre : moins de 0,03%,
• bore : 0,0005% à 0,01%.

In an exemplary embodiment, a sheet of hot-rolled steel sheet of the following weight composition is used:

• carbon: 0.15% to 0.25%,
• manganese: 0.8% to 1.5%,
• silicon: 0.1% to 0.35%,
• chromium: 0.01% to 0.2%,
• titanium: less than 0.1%,
• aluminum: less than 0.1%,
• phosphorus: less than 0.05%,
• sulfur: less than 0.03%,
• boron: 0.0005% to 0.01%.

One piece is made from the cold-rolled steel sheet 1 mm thick and continuously galvanized double-sided, with a coating thickness of approximately 10 μm. In the process not forming part of the invention the sheet is austenitized at 950 ° C. before forming and quenching in the tool, the coating acting as a lubricant during shaping, in addition to its protective functions against cold corrosion, hot and against decarburization. During quenching, the alloy coating does not interfere with the extraction of heat by the tool and can promote it. After forming and quenching, it is no longer necessary to strip the part or to protect it, the base coating providing protection throughout the process.

After shaping and thereby heat treatment, the part produced is of a matte gray appearance without sag or bubble, without flaking or cracks, and not having calamine on the wafer, in section. Scanning electron microscopic observations show on the surface and in section that the coating retains a homogeneous structure and texture and that Fe-Zn alliation occurs in less than 5 minutes at 950 ° C.

The coating comprises as shown in comparative manner on the Figures 3a and 3b respectively representing, in section, the coating before and after heat treatment, a Zn diffusion interface, with a thickness of between 5 and 10 μm, is a layer formed by nodules of Zn-Fe alloy in a zinc matrix layer with a thickness of between 10 and 15 μm.

Moisture and temperature corrosion tests according to DIN 50 017 show that the coating according to the invention provides excellent protection against corrosion after 30 cycles, the surfaces of the parts keeping their gray appearance.

Table 1 below shows the loss of corrosion mass after 500 and 1000 hours of salt spray, for an uncoated reference steel, for a galvanized reference steel without heat treatment, and a steel according to two forms of the invention. Table 1. Loss of mass in g / m ² Loss of mass in g / m ² After 500 hours After 1000 hours Reference steel 450 g / m ² 1230 g / m ² Galvanized reference steel 80 g / m ² 140 g / m ² Zn coated steel after heat treatment 32 g / m ² 82 g / m ² Zn-Al coated steel after heat treatment 22 g / m ² 50 g / m ²

As can be seen, the coating after heat treatment is resistant to salt spray. In addition, this surface, composed of zinc and iron, can be phosphated in conventional surface treatment baths of the phosphating type. The corrosion tests carried out after phosphating and cataphoresis painting show excellent results. The zinc iron alloy layer also provides galvanic protection for cathodic protection type slices.

Example 2: Coating of zinc aluminum on steel (not forming part of the invention).

A 10 μm coating is applied to a sheet of about 1 mm. This coating is composed of 50 to 55% aluminum and 45 to 50% zinc with possibly a small amount of silicon.

The appearance of this sectional coating after hot forming is presented on the Figures 4a and 4b .

In hot forming, zinc, aluminum, and iron combine to form a homogeneous and adherent zinc-aluminum-iron coating. Corrosion tests show that this alloy layer provides very good protection against corrosion.

Claims (9)

1. A method for producing a part featuring very high mechanical properties by press forming from a strip of rolled, in particular hot-rolled, steel sheet intended to undergo cold forming followed by heat treatment and coated with zinc or a zinc-based alloy that provides protection of the surface and of the steel, the method comprising

   - cutting the sheet to make a sheet metal blank,

   - carrying out cold press forming departing from the sheet metal blank in order to obtain the part,

   - producing, after press forming, by means of heat treatment, an alloyed intermetallic compound on the surface, providing protection against corrosion and against decarburization of the steel, said compound being obtained by transforming the coating into an intermetallic alloy by an increase in temperature of more than 700 °C,

   - cooling the part obtained by press forming so as to undergo quenching at a speed greater than the critical quenching speed,

   - removing, by cutting, the surplus sheet metal necessary for the press forming operation.
2. The method according to claim 1, characterized in that the zinc or zinc-based alloy of the coating has a thickness between 5 µm and 30 µm.
3. The method according to claim 1 or 2, characterized in that the alloyed compound is a zinc-iron-based compound also comprising silicon.
4. The method according to any of claims 1 to 3, characterized in that the part is subjected to an increase in temperature of between 700 °C and 1200 °C in a furnace with an uncontrolled atmosphere.
5. The method according to any of claims 1 to 4, characterized in that the increase in temperature is greater than 900 °C, but not exceeding 1200 °C.
6. A part featuring very high mechanical properties, formed by a cold press-formed blank and cut from a strip of rolled, in particular hot-rolled, steel sheet intended to undergo cold forming followed by heat treatment and coated with zinc or a zinc-based alloy providing protection of the surface and the steel, the coating being transformed, after press forming, by heat treatment into a zinc-iron-based alloyed compound on the surface providing protection against corrosion and against decarburization of the steel, said heat treatment being implemented by means of an increase in temperature of more than 700 °C, the part obtained by press forming being cooled so as to undergo quenching at a speed greater than the critical quenching speed.
7. The part according to claim 6, characterized in that the thickness of the coating is between 5 µm and 30 µm.
8. The part according to claim 6 or 7, characterized in that said strip of sheet steel comprises 0.15 to 0.25 % carbon, 0.8 to 1.5 % manganese, 0.1 to 0.35 % silicon, 0.01 to 0.2 % chrome, 0 to 0.1 % titanium, 0 to 0.1 % aluminium, 0 to 0.05 % phosphorus, 0 to 0.03 % sulfur and 0.0005 to 0.01 % boron in % by weight.
9. The part according to any of claims 6 to 8, characterized in that said strip of sheet steel is a strip of hot-rolled steel, then cold-rolled.

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