Process for the manufacture of ferrosilicon or silicon alloys containing strontium

A process is described for the manufacture of ferrosilicon or silicon alloys containing strontium and having a low aluminum and calcium content, in which a strontium compound is introduced together with an alkaline earth metal, an alkaline earth metal-containing alloy or calcium carbide as reducing agent into the molten ferrosilicon or silicon. The process is distinguished by low industrial expense and good strontium yields.

The present invention relates to a process for the manufacture of 
ferrosilicon or silicon alloys containing strontium and having a low 
aluminium and calcium content, such as are described, for example, in 
DE-PS 14 33 429. Alloys of this type are used above all in the field of 
foundry work when manufacturing cast iron using lamellar, nodular or 
vermicular graphite or when manufacturing silicon-containing aluminium 
castings, the alloys being suitable for special inoculation problems owing 
to their special properties. Strontium-containing ferrosilicon alloys 
effectively suppress chill tendency and in this manner improve the 
structure and properties of the cast iron. Since, in certain 
circumstances, the elements aluminium and calcium increase the formation 
of defects in the casting, the aluminium and calcium content in the alloy 
should be kept as low as possible. 
From DE-PS 15 08 273 there is known a process for the manufacture of 
strontium-containing ferrosilicon having a low calcium content in an arc 
furnace, which process comprises two stages. First of all, a master alloy 
containing from 15 to 55% strontium and from 40 to 75% silicon is prepared 
from quartzite, celestine having a ratio of strontium to calcium of at 
least 10:1 and a carbon-containing reducing agent and the master alloy is 
then added to molten ferrosilicon in such an amount that the resulting 
alloy has a strontium content of at least 0.5%. Although the yield with 
regard to the strontium is good, the two-stage process is industrially 
rather expensive and the loss of heat during the transferring operation is 
unfavourable with regard to energy. 
To avoid these disadvantages, an attempt was made according to U.S. Pat. 
No. 4,017,310 to manufacture strontium-containing alloys of this type in a 
one-stage process by introducing a strontium compound, such as, for 
example, the oxide, carbonate or sulphate, and carbon into the molten 
ferrosilicon or silicon. In order, however, to achieve an optimum 
strontium yield, the strontium compound must be pelletised together with 
the carbon, which, however, gives rise to additional operating and 
investment costs. 
The problem underlying the present invention is, therefore, to develop a 
process for the manufacture of ferrosilicon or silicon alloys containing 
strontium and having a low aluminium and calcium content which does not 
have the disadvantages mentioned and which ensures good strontium yields 
despite low industrial expense. 
This problem is solved according to the invention by introducing the 
strontium compound together with an alkaline earth metal, an alkaline 
earth metal-containing alloy or calcium carbide as reducing agent into the 
molten ferrosilicon or silicon. Surprisingly, it has been found that, when 
using the reducing agents according to the invention, the strontium yield 
is good and that, even when using calcium carbide, the calcium content in 
the alloy is relatively low. 
In the process according to the invention, the ferrosilicon, which has a 
silicon content of from 30 to 90%, or the silicon is melted in the 
customary industrial devices, such as, for example, in an induction 
furnace or in a low shaft furnace. 
Preferred compositions of the ferrosilicon are FeSi 50 and FeSi 75 having a 
silicon proportion of between 40 and 65% and between 65 and 80%, 
respectively. Subsequently, the smelt can be subjected to a short oxygen 
treatment and the slag can be removed. The mixture of strontium compound 
and reducing agent is then introduced into the smelt and the reaction 
mixture is left for from 1 to 30 minutes, especially from 5 to 15 minutes, 
at a temperature of from 1300.degree. to 1500.degree. C. In this manner, 
strontium values of from 0.1 to 20% may occur in the alloy. Suitable 
strontium compounds are, in principle, all reducible derivatives of 
strontium, but it is preferable to use compounds containing oxygen, such 
as, for example, the oxide, carbonate, hydroxide or sulphate of strontium. 
Suitable reducing agents are, above all, metals or alloys of alkaline earth 
metals. In this respect, calcium, magnesium, calcium-silicon and 
ferrosilicon-magnesium have proved especially advantageous. 
In addition to these alkaline earth metals or the alloys thereof, calcium 
carbide, such as is commercially available as an industrial product having 
a content of from 70 to 80% CaC.sub.2, is also suitable for the 
manufacture of the alloys concerned, although it contains additional 
calcium-containing compounds, such as, for example, calcium oxide, as 
secondary constituents. 
With regard to the ratios by weight of strontium compound to reducing 
agent, the highest yields of strontium can be achieved if approximately 
stoichiometric amounts of the reactants are used. If the proportion of 
strontium compound is larger than this, the yields naturally decrease 
owing to the lack of reducing agent, while if the proportion of 
calcium-containing reducing agent is too high, the calcium proportion in 
the alloy exceeds the desired value. 
With the aid of the process according to the invention, it is possible to 
manufacture ferrosilicon or silicon alloys containing strontium using 
industrially relatively simple means and without too great an expenditure 
of energy, the process having special advantages owing to the good 
strontium yields and, at the same time, low calcium contents in the 
alloys. 
The following Examples are intended to explain the invention in detail 
without, however, limiting it thereto.

EXAMPLE 1 
10 kg of a ferrosilicon alloy (FeSi 75) having the following composition 
Si: 79.2% 
Fe: 16.6% 
Al: 1.84% 
Ca: 1.19% 
Ti: 0.05% 
C: not determined 
Sr: &lt;0.01% 
are melted in an induction furnace and subjected to an oxygen treatment for 
15 minutes. After being left to stand for five minutes, the slag is drawn 
off, the alloy having the following analysis: 
Si: 76.5% 
Fe: 21.7% 
Al: 0.48% 
Ca: 0.06% 
Ti: 0.07% 
C: 0.06% 
Sr: &lt;0.1% 
Subsequently, a mixture comprising 565 g of strontium carbonate and 353 g 
of industrial calcium carbide (73%) is stirred into the smelt. After a 
reaction time of 15 minutes, the slag is drawn off from the alloy and the 
alloy is cast, the following final values being achieved in the alloy: 
Si: 74.0% 
Fe: 19.9% 
Al: 0.56% 
Ca: 1.2% 
Ti: 0.06% 
C: 0.48% 
Sr: 2.4% 
The yield of strontium is 72%. 
EXAMPLE 2 
10 kg of FeSi 75 are melted as in Example 1 in an induction furnace. After 
the treatment with oxygen and removal of the slag, a mixture of 400 g of 
strontium carbonate and 71.5 g of fine magnesium filings is introduced 
into the liquid alloy. The smelt is then left to stand for approximately 
15 minutes before the slag is again drawn off from the alloy and the alloy 
is cast. After this treatment, the alloy has the following analysis: 
Si: 76.5% 
Fe: 21.0% 
Al: 0.52% 
Ca: 0.09% 
Ti: 0.06% 
C: 0.11% 
Mg: 0.2% 
Sr: 0.7% 
The yield of strontium is 29.5%. 
EXAMPLE 3 
10 kg of FeSi are melted as in Example 1 in an induction furnace and 
subjected to an oxygen treatment for 15 minutes, the slag is drawn off and 
then a mixture of 400 g of strontium carbonate and 34 g of calcium-silicon 
having a particle size of less than 0.1 mm is added. After a reaction time 
of 15 minutes, the slag is drawn off from the alloy and the alloy is cast, 
the final alloy having the following analysis: 
Si: 76.9% 
Fe: 19.1% 
Al: 0.89% 
Ca: 0.38% 
Ti: 0.06% 
Sr: 1.0% 
The yield, based on the strontium, is 42.1% 
EXAMPLE 4 
10 kg of FeSi 75 are melted in an induction furnace according to Example 1 
and oxygen is blown into the melt for 15 minutes. After being left to 
stand for 5 minutes, the slag is removed and a mixture of 400 g of 
strontium carbonate and 1300 g of fine-grained FeSiMg 5 having the 
following composition is stirred into the smelt: 
Fe: 40.5% 
Si: 47.1% 
Al: 1.41% 
Mg: 5.5% 
Ca: 2.9% 
RE: 0.8% 
(RE=rare earths) 
After a treatment time of 15 minutes, the slag is drawn off and the alloy 
is cast, the alloy having the following analysis: 
Fe: 25.0% 
Si: 73.0% 
Al: 0.35% 
Ca: 0.09% 
Ti: 0.06% 
C: 0.22% 
Mg: 0.2% 
Sr: 0.4% 
This corresponds to a strontium yield of 16.8% 
EXAMPLE 5 
8 kg of silicon metal having the following composition 
Si: 99% 
Ca: 0.01% 
Al: 0.18% 
Fe: 0.5% 
C: not determined 
Sr: &lt;0.01% 
are melted in an induction furnace. Subsequently, the slag is removed and 5 
kg of a mixture of 93% by weight of strontium carbonate and 8% by weight 
of industrial calcium carbide are introduced into the smelt. After a 
reaction time of 10 minutes, the slag is again removed, analysis of the 
alloy giving the following values: 
Si: 85.4% 
Fe: 0.9% 
Al: &lt;0.1% 
Ca: 0.32% 
Ti: 0.02% 
C: 0.06% 
Sr: 12.3% 
The strontium yield is 48.1%.