DE1508221B2 - Master alloy for the production of spheroidal graphite cast iron - Google Patents

Description

57 to 70% Magnesium, 10 to 35 ° / o Silicon and / or copper and / or nickel, Ibis 8th% Rare earth metals, 4 to 6% Calcium, Ibis 4% Aluminum, rest iron

contains.

2. master alloy according to claim 1, characterized in that it

64 to 66% magnesium,
7 to .8% rare earth metals,
4 to 4.5% calcium,

less than 4% aluminum, preferably 3.5% aluminum,

less than 3% iron, preferably

1.5% iron,
Remainder silicon and / or nickel and / or

copper

contains.

3. master alloy according to claims 1 or 2, characterized in that it contains up to 5% tin contains.

The invention relates to a master alloy suitable for the treatment of cast iron melts in order to be used in such iron melts precipitate the carbon in the form of spheroidal graphite.

As the element inducing nodular graphite formation, magnesium has predominantly proven itself in practice Dimensions introduced. It is already known to melt magnesium metal in unalloyed form in cast iron to be brought in in a variety of ways. But also magnesium-containing alloys based on iron, silicon or nickel with a magnesium content of up to 55% are used for the stated purpose. Such known alloys have, for example, the composition 25 to 55% magnesium, 3 to 35% iron, the rest more than 35% silicon (German Interpretation document 1 021 395). Other known alloys contain up to 50% magnesium up to 10% calcium, at least 25% silicon, remainder iron, the calcium having a beneficial effect burns off the magnesium and absorbs it into the melt (USA.-Patent 2,837,422). It is also known that ferro-silicon masterpieces contain more than 20% magnesium show less magnesium uptake by the cast iron and a vigorous reaction. Man has therefore tried to add copper or nickel as well as rare earth metals, calcium and aluminum to bring about a better magnesium yield and a quieter course of the reaction (Wastschenko / Sofroni; "Magnesium treated cast iron", Leipzig, 1960, Tab. 1 p. 13 ff). In In this context, the vaccination effect of aluminum and calcium is known (Piwowarsky,

ίο »High quality cast iron«, 1951, p. 174, plate 25). Tin-containing silicon-based inoculation alloys are also used to achieve a pearlitic matrix in cast iron used, the z. B. aluminum, calcium or cerium may contain (USA.Patent 2 955 933). One also has the severity of the reaction of master alloys with a high magnesium content also reduced by the fact that magnesium-nickel alloys with z. B. 56 or 66% magnesium are nitrided before they are used. Instead of or in addition to nickel, such alloys can also contain silicon, Contain copper, iron and calcium (Austrian patent specification 184 199). It is also a "steady, smooth reaction with high magnesium yield through the use of magnesium alloys known that with a composition of 25 to 35% magnesium, 2.8 to 5% calcium, 35 to 60% silicon, the remainder essentially iron, a very specific ratio of magnesium to calcium and may also contain rare earth metals (Austrian Patent 197,414). The prior art also includes master alloys for treatment of cast iron melts, which are composed of 10 to 73% magnesium and 27 to 90% mischmetal (U.S. Patent 2,792,300).

According to a known proposal, however, magnesium-free master alloys are also suitable for production of spheroidal graphite cast iron, which has a composition of 15 to 65% rare earth metals, 12 to 45% silicon, a maximum of 6% calcium and a maximum of 65% iron (French patent specification 82 937).

The manufacture of spheroidal graphite cast iron by treating molten iron with magnesium metal or with master alloys with a content of over 50% magnesium has in practice in in very few cases led to technically and economically satisfactory results. Procedure that make use of the introduction of magnesium metal, require a high level of equipment and are also usually cumbersome to handle in operational practice, while for example high magnesium-containing alloys with a relatively high content of rare earth metals are treated in in a way that bears no relation to the success achieved.

The invention is based on the object of master alloys for the treatment of iron melts for the purpose of producing spheroidal graphite cast iron with a high magnesium content ensure a relatively high magnesium yield by adding certain other components and ensure a smooth reaction process despite the high magnesium content.

The invention solves this problem with a master alloy for treating a molten iron for the Production of cast iron with spheroidal graphite based on magnesium as well as silicon and / or copper

and / or nickel, containing further spheroidal graphite-forming and inoculating additives.

The master alloy of the invention is characterized in that it

57 to 70% magnesium,

10 to 35% silicon and / or nickel
and / or copper,

1 to 8% rare earth metals,

4 to 6% calcium,

1 to 4% aluminum,

Remainder iron

contains.

The alloys according to the invention can expediently contain up to 5% tin. One of those The tin content in the master alloy serves as a pearlite stabilizer for the iron melts to be treated.

With alloys of the aforementioned type it is possible in an advantageous manner, despite relatively high Magnesium content still a good magnesium yield and thus a complete transfer to achieve the graphite in the spherical shape. By coordinating the additional components, in particular of the rare earth metals, calcium and aluminum, it is possible to reduce the vapor pressure of magnesium reduce in such a way that a relatively smooth course of the reaction is brought about and the magnesium is absorbed by the molten iron with high yield. With the master alloys according to the invention it is therefore possible to get by with very small amounts of alloy and the To bring about spheroidal graphite formation in iron melts in a satisfactory manner. In general, the Amount of alloy with which the iron melt is treated, between 0.3 and 0.8%, based on the Melt.

The alloy is introduced in a manner known per se and is not the subject of the invention. Known types of introduction use, for example, a diving bell to specifically light To push alloys of the type mentioned under the bath surface and an effective reaction to achieve with the iron melt. The iron melts can, for. B. from the sour or basic delivered hot blast cupola can be obtained. By using the alloys according to the invention extremely high master alloy yield achievable in a melt treatment, including the product from magnesium content and magnesium yield is to be understood, only makes in a particularly favorable manner a very small amount of master alloy must be added. This is also only very advantageous causes a slight increase in the silicon content. This point of view is e.g. B. of importance when a Cast iron melted from a blast furnace with a given Si content can be treated got to. In the case of such pig iron, the reserves for an increase in the Si content are achieved with use a Mg-Si alloy are usually inevitable, very low. The use of the invention Alloy is also advantageous if a material made of cast iron with spheroidal graphite is to be produced, the Si content of which z. B. for reasons of notched impact strength to an amount from Z. B. 2.1% or lower is limited.

The master alloys are expediently introduced into the cast iron or steel melt to be treated with the aid of an immersion bell. The treatment temperature is in a range from 1350 to 1550 ^° C.

The alloys can be used with increased efficiency in terms of spheroidal graphite formation, i.e. H. with even higher Mg yield, can be used if all or part of the silicon is used instead Nickel is used in the master alloy. But copper can also represent silicon in whole or in part. It is true that this does not reduce the Mg yield

ίο significantly increased, but such a master alloy takes place then a preferred use when making spheroidal graphite cast iron with A ferritic-pearlitic structure is sought in the as-cast state.

An alloy of the range according to the invention, in which part of the silicon is replaced by tin, is finally used with particular advantage when a predominantly pearlitic structure is sought in the as-cast state. For purposes at

ao those for the production of cast iron with spheroidal graphite high-purity and low-manganese pig iron An alloy of the composition has been found to be advantageous for the treatment of molten iron

66% magnesium,

17.0% silicon,

7.5% rare earth metals,

4.5% calcium,

3.5% aluminum,

1.5% iron

proven.

In this case, nickel and / or copper can also take the place of silicon, for example if in the first In the case of an optimization of the magnesium yield under given melting conditions or via the alloying of copper, the production of spheroidal graphite cast iron with a ferritic-pearlitic one Structure is sought. The elements silicon, nickel and copper can also be used side by side present in an amount up to 17%.

However, some of the silicon can also be replaced by the alloy component tin. In this case the alloy contains 12% silicon and 5% tin. Such a type of alloy has proven to be advantageous for the treatment of cast iron melts for the production of castings with a predominantly pearlitic structure in the as-cast state.
The master alloys of the invention are used for the production of spheroidal graphite cast iron by treating molten iron at temperatures of 1350 to 1550.degree. The melts are subjected to suitable and customary pretreatments such as deoxidation and desulfurization, especially before the tin-containing master alloys are used. Above all, however, the melts should also contain no or less than 0.05% proportions of interfering elements, in particular no lead, bismuth and no more than 0.04% titanium. Elements that bring about carbide stabilization should, if possible, only be contained in traces or small proportions in the melt, in particular it is advantageous if the proportions of manganese, chromium, vanadium, tungsten and molybdenum are less than 0.1% in total and phosphorus is less than 0, 05% and sulfur below 0.03%.

The technical advancement and the benefit of using the high magnesium master alloys with simultaneously coordinated

hold further alloy components in the master alloy according to the invention for the production of Cast iron with spheroidal graphite can be seen quite generally in the fact that the master alloy additive amounts in in each case are smaller than with previously known master alloys of comparable composition. Through this The production of spheroidal graphite cast iron with relatively low levels of Ni is only possible and / or Si allows. This also has a beneficial effect on the inevitable associated with the treatment Temperature loss. Finally, the diving bell used can also be made smaller, which has an advantageous effect in terms of temperature loss and operational costs.

The invention is explained in more detail using the following exemplary embodiments.

example 1

For the production of spheroidal graphite cast iron, one in an acidic for the Mg treatment Hot blast cupola melted and then overheated in the mains frequency furnace the analysis 3.6 to 3.8% C, 0.1% Mn, 1.5 to 1.8% Si, 0.05% P and 0.04 to 0.05% S in the Immersion treatment of 800 kg of melt at a temperature of 1500 ° C 8 kg (1%) of a known one Master alloy with 31 o / o Mg, 4.2% Ca, 7 o / o Fe, remainder Si needed. With an initial sulfur content of 0.05% and a magnesium content of 0.07% treated cast iron results in a magnesium yield of around 34% and an alloy

31 · 34
yield of = 10.5%.

The structure shows a practically 100 percent formation of the graphite in the spherical shape and is in the As-cast state with a wall thickness of 25 mm is predominantly ferritic.

Example 2

The same cast iron is used with a master alloy with unchanged casting conditions treated which contains 60% magnesium, 6.0% calcium, 1% aluminum, 3.8% iron, 1.2% rare earth metals, The remainder contains silicon to compensate for any interfering elements that may be present. From this master alloy become 0.62%, i.e. H. 5.0 kg, needed to treat 800 kg of melt if you use the same The aim is to achieve a residual Mg content of 0.07% in the treated cast iron. This results in a smaller one Magnesium yield of 28%, but therefor

a master alloy yield of

60-28

= 16.8%.

" ° 100

The structure shows a practically 100 percent formation of the graphite in the spherical shape and almost ferritic structure in the as-cast state.

ao example3

For magnesium treatment of the cast iron of the composition of Example 1 with a master alloy composed of 60% magnesium, 7.5 0/0 rare earth metals, 4.5% Ca, 3.0 _^0/0 Al, 17% Si, balance Fe are 4 kg Master alloy is required if one is aiming for the same residual Mg content in the treated cast iron of 0.07%. The rare earth metals no longer only serve to eliminate interfering elements, but also to actively increase the Mg yield.

This results in a magnesium yield

of 35% and a master alloy yield of

= 21.0 0/0.

The effectiveness of this master alloy is therefore twice as great as that in practice today Dip treatment mostly used master alloy with about 30% magnesium.

Claims (1)

Patent claims: 1. Master alloy for treating a molten iron for the production of cast iron with Containing spheroidal graphite based on magnesium and silicon and / or copper and / or nickel further spheroidal graphite forming and inoculating additives, characterized in that they