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Ferrosilicon alloyFerrosilicon is an alloy of iron and silicon with a typical silicon content by weight of 15&#;90%. It contains a high proportion of iron silicides.[1]
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Ferrosilicon is produced by reduction of silica or sand with coke in the presence of iron. Typical sources of iron are scrap iron or millscale. Ferrosilicons with silicon content up to about 15% are made in blast furnaces lined with acid fire bricks.[2]
Ferrosilicons with higher silicon content are made in electric arc furnaces.[2] The usual formulations on the market are ferrosilicons with 15%, 45%, 75%, and 90% silicon. The remainder is iron, with about 2% consisting of other elements like aluminium and calcium. An overabundance of silica is used to prevent formation of silicon carbide. Microsilica is a useful byproduct.
A mineral perryite is similar to ferrosilicon, with its composition Fe5Si2. In contact with water, ferrosilicon may slowly produce hydrogen. The reaction, which is accelerated in the presence of base, is used for hydrogen production. The melting point and density of ferrosilicon depends on its silicon content, with two nearly-eutectic areas, one near Fe2Si and second spanning FeSi2-FeSi3 composition range.
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Si mass fraction (%) 0 20 35 50 60 80 100 Solidus point (°C) Liquidus point (°C) Density (g/cm3) 7.87 6.76 5.65 5.1 4.27 3.44 2.33[
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Ferrosilicon is used as a source of silicon to reduce metals from their oxides and to deoxidize steel and other ferrous alloys. This prevents the loss of carbon from the molten steel (so called blocking the heat); ferromanganese, spiegeleisen, calcium silicides, and many other materials are used for the same purpose.[5] It can be used to make other ferroalloys. Ferrosilicon is also used for manufacture of silicon, corrosion-resistant and high-temperature-resistant ferrous silicon alloys, and silicon steel for electromotors and transformer cores. In the manufacture of cast iron, ferrosilicon is used for inoculation of the iron to accelerate graphitization. In arc welding, ferrosilicon can be found in some electrode coatings.
Ferrosilicon is a basis for manufacture of prealloys like magnesium ferrosilicon (MgFeSi), used for production of ductile iron. MgFeSi contains 3&#;42% magnesium and small amounts of rare-earth metals. Ferrosilicon is also important as an additive to cast irons for controlling the initial content of silicon.
Magnesium ferrosilicon is instrumental in the formation of nodules, which give ductile iron its flexible property. Unlike gray cast iron, which forms graphite flakes, ductile iron contains graphite nodules, or pores, which make cracking more difficult.
Ferrosilicon is also used in the Pidgeon process to make magnesium from dolomite.
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Treatment of high-silicon ferrosilicon with hydrogen chloride is the basis of the industrial synthesis of trichlorosilane.
Ferrosilicon is also used in a ratio of 3&#;3.5% in the manufacture of sheets for the magnetic circuit of electrical transformers.
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The method has been in use since World War I. Prior to this, the process and purity of hydrogen generation relying on steam passing over hot iron was difficult to control.[6] The chemical reaction uses sodium hydroxide (NaOH), ferrosilicon, and water (H2O). While in the "silicol" process, a heavy steel pressure vessel is filled with sodium hydroxide and ferrosilicon, and upon closing, a controlled amount of water is added; the dissolving of the hydroxide heats the mixture to about 200 °F (93 °C) and starts the reaction; sodium silicate, hydrogen and steam are produced.[7] The overall reaction of the process is believed to be:[2][note 1]
Ferrosilicon is used by the military to quickly produce hydrogen for balloons by the ferrosilicon method. The generator may be small enough to fit in a truck and requires only a small amount of electric power, the materials are stable and not combustible, and they do not generate hydrogen until mixed.[8]
One report notes that this method of hydrogen production wasn't thoroughly investigated for about century despite being reported by the US military in the beginning of 20th century.[2]
The iron is intentionally omitted
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The CAMSIZER P4 dynamic image analyzer determines particle size and shape in a range from 20 μm to 30 mm and is therefore ideally suited for the routine analysis of ferrosilicon. The particles under investigation are conveyed by a vibratory chute into the measurement zone where they are passing a planar light source in free fall. The resulting shadow projections are captured by a camera system and evaluated in real time. The CAMSIZER P4 features the unique Dual-Camera Technology. One camera (ZOOM) detects fine particles with great accuracy and a second camera (BASIC) with lower magnification, but larger field of view detects large particle simultaneously. This is an invaluable advantage because the CAMSIZER P4 can analyze all particles within one sample without any hardware adjustments and without losing accuracy for either very large or very fine particles. Thanks to the two cameras, ideal measurement conditions can be established for the entire size range, the analysis is therefore extremely convenient and accurate.
The huge advantage of this arrangement is the vast amount of sample that can be processed in a very short analysis time of only a few minutes. The CAMSIZER P4 is maintenance-free and therefore offers a faster and more reliable alternative to traditional sieve analysis. Thanks to its robust design, the CAMSIZER P4 unsusceptible to vibration and dust. The instrument can therefore operate in an industrial plant as well as in a laboratory environment.
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