Purity (Grade): Fe:59-62% P<0.1%.S<0.1
Supply Capacity: 40,000 MT/Month
Size: 0-10mm & 10-40mm & 10-25mm
Packing: bulk with container and Vessel
Moisture: Max 1.5%
Inspection: Loading survey Quality-Quantity report in POL.
Port of Loading: Bandare Abbas IRAN (ShahidRajai Port).
Documents: Original SGS reports, Shipping B/L, CO, Commercial invoice, Packing List
Delivery: 30 Days
Payment and price: Negotiable.
Iron Ore Tetsing And Analysis
Iron ores are rocks and minerals from which metallic iron can be economically extracted. The Iron ores are usually rich in iron oxides and vary in color from dark grey, bright yellow, deep purple, to rusty red. The iron itself is usually found in the form of magnetite (Fe3O4), hematite (Fe2O3), goethite [FeO (OH)], limonite [FeO (OH).n (H2O)] or siderite (FeCO3). Iron Ores carrying very high quantities of hematite or magnetite (greater than ~60% iron) are known as "natural ore" or "direct shipping ore", meaning that those can be fed directly into iron-making blast furnaces. Iron ore is the raw material used to make pig iron, which is one of the main raw materials to make steel. 98% of the mined iron ore is used to make steel. Iron Ore is the fourth most abundant element in the Earth's crust.
Effects of Iron Ore Elements on Steel Making The inclusion of even small amounts of some elements can have profound effects on the behavioral characteristics of a batch of iron or the operation of a smelter. These effects can be both good and bad, some catastrophically bad. Some chemicals are deliberately added such as flux which makes a blast furnace more efficient. Others are added because they make the iron more fluid, harder, or give it some other desirable quality. The choice of ore, fuel, and flux determine how the slag behaves and the operational characteristics of the iron produced. Typically, iron ore contains a host of elements the effect of which in Steel making are described below. Silica (SiO2) is almost always present in iron ore & is one of the principal deoxidizers used in steelmaking. Most of it is slagged off during the smelting process. At temperatures above 1300 °C some will be reduced and form an alloy with the iron. The hotter the furnace, the more silicon will be present in the iron. The major effect of silicon is to promote the formation of gray iron. Gray iron is less brittle and easier to finish than white iron. It is preferred for casting purposes for this reason. In low-carbon steels, silicon is generally detrimental to surface quality. Phosphorous increases strength and hardness and decreases ductility and notch impact toughness of steel. The adverse effects on ductility and toughness are greater in quenched and tempered higher-carbon steels. Phosphorous levels are normally controlled to low levels. Higher phosphorus is specified in low-carbon free-machining steels to improve machinability. Phosphorous is a deleterious contaminant because it makes steel brittle, even at concentrations of as little as 0.6%. Phosphorus cannot be easily removed by fluxing or smelting, and so iron ores must generally be low in phosphorus to begin with. Sulfur decreases ductility and notch impact toughness especially in the transverse direction. Weldability decreases with increasing sulfur content. Sulfur is found primarily in the form of sulfide inclusions. Sulfur levels are normally controlled to low levels. The only exception is free-machining steels, where sulfur is added to improve machinability. Sulfur can be removed from ores by roasting and washing. Roasting oxidizes sulfur to form sulfur dioxide which either escapes into the atmosphere or can be washed out. In warm climates it is possible to leave pyritic ore out in the rain. The combined action of rain, bacteria, and heat oxidize the sulfides to sulfates, which are water soluble. Aluminum is widely used as a deoxidizer. Aluminum can control austenite grain growth in reheated steels and is therefore added to control grain size. Aluminum is the most effective alloy in controlling grain growth prior to quenching. Titanium, zirconium, and vanadium are also valuable grain growth inhibitors, but there carbides are difficult to dissolve into solution in austenite. However, as per few experts, it does increase the viscosity of the slag. This will have a number of adverse effects on furnace operation. The thicker slag will slow the descent of the charge, prolonging the process. High aluminum will also make it more difficult to tap off the liquid slag. Copper in significant amounts is detrimental to hot-working steels. Copper negatively affects forge welding, but does not seriously affect arc or oxyacetylene welding. Copper can be detrimental to surface quality. Copper is beneficial to atmospheric corrosion resistance when present in amounts exceeding 0.20%. Weathering steels are sold having greater than 0.20% Copper. Lead is virtually insoluble in liquid or solid steel. However, lead is sometimes added to carbon and alloy steels by means of mechanical dispersion during pouring to improve the machinability. Nickel is a ferrite strengthener. Nickel does not form carbides in steel. It remains in solution in ferrite, strengthening and toughening the ferrite phase. Nickel increases the hardenability and impact strength of steels. Titanium is used to retard grain growth and thus improve toughness. Titanium is also used to achieve improvements in inclusion characteristics. Titanium causes sulfide inclusions to be globular rather than elongated thus improving toughness and ductility in transverse bending. Vanadium increases the yield strength and the tensile strength of carbon steel. The addition of small amounts of Vanadium can significantly increase the strength of steels. Vanadium is one of the primary contributors to precipitation strengthening in micro alloyed steels. When thermo mechanical processing is properly controlled the ferrite grain size is refined and there is a corresponding increase in toughness. The impact transition temperature also increases when vanadium is added. BASICS OF SOME IMPORTANT ELEMENT ANALYSIS OF IRON ORE 1. Analysis of Iron content as Fe% Laboratory Sample of Iron Ore is dissolved by boiling in 1 : 1 Hydrochloric Solution. To the boiling solution Stannous Chloride solution is added to reduce Iron with slight excess. The unused stannous chloride is destroyed by Mercuric Chloride & the reduced Iron is titrated with standard Dichromate solution using Barium Diphenylamine Sulphonate. 2. Analysis Ferrous Iron as FeO% Ferrous Iron ore is determined by dissolving Laboratory Sample of Iron Ore diluted Hydrochloric acid in the atmosphere of Carbon Di Oxide & filtrating with Standard Potassium Dichromate solution. 3. Analysis of Silica in Iron Ore as SiO2% Laboratory Sample of Iron Ore is dissolved in Hydrochloric acid & baked for dehydration of Silica at 110 deg C. It is again dissolved with Hydrochloric acid & diluted with water, boiled, filtered & the residue is ignited and Silica is determined by Hydrofluorisation. The residue is fused with Sodium Carbonate & extracted with Hydrochloric Acid, added to the main filtrate & it is measured for further analysis. 4. Analysis of Alumina in Iron Ore as Al2O3% To the Solution of the Iron Ore Laboratory Sample Sodium Phosphate is added & the acidity adjusted. Sodium Thiosulphate when added in excess reduces Iron to the Ferrous State & precipitates Aluminum as Phosphate. Alumina is calculated from the weight of Aluminum Phosphate. 5. Analysis of Phosphorous in Iron Ore The laboratory sample of Iron Ore is dissolved in Hydrochloric Acid & evaporated to dryness nearly. Add Nitric Acid (10 cc) two three times to drive out Hydrochloric acid & dehydrate Silica. Add Water to dissolve the sample and filter the solution & collect the solution in a conical flask. Then precipitate the Phosphorous with Aluminum Molybdate after making properly acidic concentration & appropriate temperature. Filter the precipitate which after making acid free is dissolved in known excess of standard alkali. The unreacted alkali is back titrated with standard Nitric Acid. 6. Analysis of Sulphur in Iron Ore Oxidation of Sulphur in Iron Ore is done by Bromine & Concentrated Nitric Acid. After that Acid Mixture (Hydrochloric Acid + Nitric Acid) is added for decomposition at lower heat. Evaporate the solution to dryness & cool. Make the solution with Hydrochloric Acid. The Iron is removed by Methyl Iso Butyl Ketone. After that Sulphur in the solution is precipitated with Barium Chloride as Barium Sulphate from which Sulphur content is analysed. Analysis of Mn, Ti, CaO, MgO, Na2O, K2O & Trace Analysis of Arsenic, Nickel, Copper, Lead, Zinc, Vanadium etc. in Iron Ore is carried out as per the requirement. Iron ore with Iran-Khaf Origin as follow: NAME OF COMMODITY:Iron ore Magnetite finegrade Fe: 59/61%. QUANTITY: 10,000 MT per Month. SPECIFICATIONS:
Element |
Base% |
Rejection |
Fe Total |
61 % |
BELOW 59% |
FeO |
16% |
BELOW 14% |
Al2O3 |
1.5% |
ABOVE 3% |
SiO2 |
5% |
ABOVE 7% |
TiO2 |
0.2% |
ABOVE 0.5% |
S |
0.07% |
ABOVE 0.1% |
P |
0.07% |
ABOVE 0.1% |
Moisture Max 2% SIZE: 0-10MM: 90% MAX ABOVE 10MM: 10% MAX Inspection: Container Loading SGS Quality and Quantity report in BandarAbbas Port. Packing: In Bulk with 20'FCL. (25 MT Loading Max)