EP3666415A1 - Method for producing spheroidal or vermicular graphite cast iron - Google Patents

Abstract

Process for the production of spheroidal graphite or vermicular graphite cast iron which comprises the following steps: melting the raw material into base iron, preferably in a cupola or electric furnace; transferring the base iron into a converter or a magnesium treatment and / or transport pan, the base iron in the converter or in the magnesium treatment and / or transport pan, magnesium is supplied in pure form or a magnesium-containing alloy, the magnesium content in the melt being lower than in the melt after the magnesium has been added in the converter or in the magnesium treatment and / or transport pan which is poured; • pouring the melt pretreated with magnesium into a die casting furnace at a molding and casting machine and keeping it at the casting temperature; • pouring the melt pretreated with magnesium from the die casting furnace into a ladle of the molding and pouring machine • and a final magnesium addition during the transfer the with magnesium reserved processed melt from the die casting furnace into the ladle.

Description

• Einschmelzen des Rohmaterials zu Basiseisen für die Herstellung von Gusseisen mit Kugel- oder Vermiculargraphit vorzugsweise in einem Kupol- oder Elektroofen;
• Umfüllen der Basisschmelze in eine Magnesiumbehandlungs- und Transportpfanne oder einen Konverter;
• Einfüllen der Schmelze in einen Druckgiessofen an einer Form- und Giessanlage und auf Giesstemperatur halten:
• Umfüllen der Schmelze vom Druckgiessofen in eine Giesspfanne der Form- und Giessanlage.

The invention relates to a method for producing cast iron with spheroidal graphite (GJS) or vermicular graphite (GJV), which comprises the following steps:

• Melting the raw material into base iron for the production of cast iron with spheroidal or vermicular graphite, preferably in a cupola or electric furnace;
• Transferring the base melt into a magnesium treatment and transport pan or a converter;
• Pour the melt into a die casting furnace at a molding and casting machine and keep at casting temperature:
• Transferring the melt from the die casting furnace into a ladle of the molding and casting system.

In order to obtain a ductile cast iron with a spherical graphite formation, magnesium or a magnesium-containing alloy is added to the base iron, which corresponds in composition to untreated cast iron. By treating the base iron with magnesium, the carbon is not separated out in the form of lamellar graphite, but as spheroidal graphite. The addition of magnesium, which has a high affinity for oxygen and sulfur, reduces the oxides present in the melt, it forms magnesium oxide and binds the sulfur as magnesium sulfide. The magnesium oxides and sulfides rise to the surface over their residence time in the liquid iron and slag there. Magnesium treatment increases the surface tension of the melt, which means that the graphite tends to be spherical.
In order to in turn produce cast iron with vermicular graphite, the base iron is alloyed with rare earths and a significantly reduced but also regulated addition of magnesium. Another way to generate GJV is to add a titanium and cerium-containing magnesium alloy to set the desired vermicular graphite shape.

It is known from the prior art that magnesium is added to the melt before or during filling into the die-casting furnace in order to obtain the desired graphite formation. But because of the time in the melt If the magnesium treatment decays and consequently the structure deteriorates and the mechanical properties of the castings deteriorate, the production must be interrupted from time to time and the die casting furnace partially emptied in order to carry out the magnesium treatment again.
Due to the necessary reheating of the emptied cast iron, additional energy expenditure is required, which has a negative impact on the economy of the process.

Alternatively, there is also the possibility known from the prior art of treating an untreated melt in the holding furnace with magnesium and transporting it to the molding plant and filling it there.

The disadvantage of all the known variants is that the die-casting furnaces and the transport vessels are slagged due to the magnesium treatment and the resulting slag. This means that both the container is continuously reduced in size and the outlet openings are blocked. Longer process interruptions are necessary to remove the slag in the containers and a high level of repair work must be taken into account.
In addition, the above-mentioned treatments of the melt with magnesium have a negative effect on the metallurgical quality of the melt, and the risk of carbide formation increases.

It is the object of the invention to propose a method in which the process for the production of cast iron with spheroidal graphite or vermicular graphite is optimized, the process interruption times and repair costs are reduced and the cast parts achieve a more constant quality.

This object is achieved according to the invention in that magnesium is added to the base iron in the converter in pure form or in the form of an alloy, the magnesium content in the converter being lower than in the melt which is being poured and a final magnesium addition after the magnesium has been added to the converter or. -treatment of the melt pretreated with magnesium takes place during the transfer from the die casting furnace into the ladle.

• C = 3,20% - 3,60%
• Si = 1,70% - 3,00%
• S = max. 0,080%

The process according to the invention for producing cast iron with spheroidal graphite or vermicular graphite is characterized in that the raw material is preferably melted into base iron in a cupola or electric furnace. The base iron preferably has a chemical analysis with the following components, among others:

• C = 3.20% - 3.60%
• Si = 1.70% - 3.00%
• S = max. 0.080%

The raw materials preferably have a low sulfur content in order to keep the extent of desulfurization as low as possible. The base iron is then transferred to a converter or a magnesium treatment and / or transport pan.

Magnesium is added to the base iron in the converter or in the magnesium treatment and / or transport pan, in pure form or in a magnesium-containing alloy, the magnesium content in the melt being lower than after the magnesium has been added in the converter or in the magnesium treatment and / or transport pan in the melt, which is poured into the molds. The next step is to fill the melt, which has been pretreated with magnesium, into a die-casting furnace at a molding and casting system, the melt being kept at the casting temperature. Subsequently, the melt pretreated with magnesium is poured into the ladle, with a final magnesium addition preferably in the form of a pretreatment alloy based on FeSiMg taking place during the transfer of the magnesium pretreated melt from the die casting furnace into the ladle.

The subsequent addition of magnesium only when it is poured into the ladle ensures graphite formation with spheroidal or vermicular graphite and a reduction in the growth or slagging of the converter or the magnesium treatment and / or transport ladle or the die casting furnace, since the lower Mg Content in the pretreated melt, a smaller amount of slag is formed, which adheres to the converter or the magnesium treatment and / or transport pan or in the die casting furnace. Process interruptions and cleaning cycles can thus be avoided be extended. The total life of the converter or the magnesium treatment and / or transport pan is extended.

The structure of the structure can be matched to the metallurgical condition by the individual addition of magnesium for the final treatment in the melt pretreated with magnesium during the transfer into the ladle. There is a dynamic addition of magnesium that is matched to the condition of the melt. This means that if there is a decay effect of the melt pretreated with magnesium, the magnesium addition can be increased when pouring it into the pouring ladle in order to compensate for this again.

It has been shown to be advantageous if the Mg content in the melt pretreated with magnesium in the converter or the magnesium treatment and / or transport pan does not exceed the Mg content of 0.050%.

The alloy is preferably also inoculated while the Mg is being added when it is transferred to the pouring ladle. This enables the inoculant to be added easily and can be adapted to small amounts of the melt, as a result of which small batches with the corresponding properties can be poured. The addition of the inoculant during the transfer or during the addition of magnesium can also react to a change in the metallurgical quality, the germ state of the melt by dynamically adjusting the amount of inoculant during the transfer.

The amount of magnesium which is added to the casting ladle for the final treatment during the transfer is preferably monitored and regulated by means of thermal analysis. The thermal analysis must be carried out for each batch in order to ensure complete control. This means that the amount of magnesium that is supplied can be dynamically adjusted and immediately matched to the melt.

It is preferable that the amount of inoculant added to the ladle for final treatment during transferring is also monitored and controlled by thermal analysis.

It has been shown as a preferred embodiment if the final addition of magnesium and / or addition of inoculant takes place at least 5s before the pouring in order to ensure a sufficient treatment time.

The final addition of magnesium and / or addition of inoculant preferably takes place at most 120s before casting. In addition, the decay effect of magnesium and vaccination treatment is too high. In this case, process-reliable microstructure formation cannot be ensured.

In a preferred embodiment, it has been shown that the casting ladle is always completely emptied with each pour. As a result, each addition of magnesium and / or addition of inoculant in each ladle or the melt present therein is individually coordinated. This guarantees that exactly defined conditions with regard to melt quantity, dosage and metallurgical condition can be found.

Claims (8)

Process for the production of spheroidal graphite or vermicular graphite cast iron, comprising the following steps: Melting the raw material into base iron, preferably in a cupola or electric furnace; • Transfer the base iron into a converter or a magnesium treatment and / or transport pan, the base iron in the converter or in the magnesium treatment and / or transport pan magnesium being supplied in pure form or a magnesium-containing alloy, after the magnesium addition in the converter or in the Magnesium treatment and / or transport pan the Mg content in the melt is lower than in the melt which is being poured; • Pour the melt pretreated with magnesium into a die casting furnace at a molding and casting machine and keep at casting temperature; • Transfer of the melt pretreated with magnesium from the die casting furnace into a ladle of the molding and casting system • and a final magnesium addition is made during the transfer of the melt pretreated with magnesium from the die casting furnace into the pouring ladle. A method according to claim 1, characterized in that the Mg content in the melt pretreated with magnesium in the converter or in the magnesium treatment and / or transport pan does not exceed the Mg content of 0.050%. Method according to one of claims 1 or 2, characterized in that the inoculant is also added during the Mg addition when decanting into the pouring ladle. Method according to one of claims 1 to 3, characterized in that the amount of magnesium required for the final treatment during the Transferring into the ladle is added, monitored and regulated by means of thermal analysis. A method according to claim 3, characterized in that the amount of inoculant, which is added for the final treatment during the transfer into the ladle, is monitored and regulated by means of thermal analysis. Method according to one of the preceding claims, characterized in that the final magnesium treatment in the form of a pretreatment alloy based on FeSiMg and / or the addition of inoculant preferably takes place at least 5 seconds prior to casting Method according to one of the preceding claims, characterized in that the final magnesium treatment and / or vaccine addition takes place at most 120s before casting. Method according to one of the preceding claims, characterized in that the ladle is always completely emptied with each pour.