TMA International Private Limited

1. Steel Production: Enhances strength and toughness.
2. Ferroalloy Manufacturing: Used in ferrochrome and ferrosilicon production.
3. High-Strength Steel: Improves properties of stainless and tool steel.
4. Electronics: Boosts electrical conductivity in batteries and transformers.

1. Improved Steel Quality: Increases strength, hardness, and oxidation resistance.
2. Cost-Effective: More affordable than pure silicon or manganese for alloying.
3. Enhanced Durability: Strengthens steel and other alloys, making them more durable for industrial applications.

Product Descriptions:

High carbon ferro chrome is a type of ferroalloy, that is, an alloy of chromium and iron, generally containing 50 to 70% chromium by weight.

Ferro chrome is produced by electric arc carbothermic reduction of chromite. Most of the global output is produced in South Africa, Kazakhstan and India, which have large domestic chromite resources. Increasing amounts are coming from Russia and China. Production of steel, especially that of stainless steel with chromium content of 10 to 20%, is the largest consumer and the main application of ferro chrome.

Product Descriptions:

Low Carbon Ferro Manganese (LCFeMn) & Medium Carbon Ferro Manganese is mainly used for producing E6013 electrodes. Ferro manganese is used in producing steel for being an excellent deoxidizer and desulfurizer.

Product Descriptions:

Ferro Calcium Silicon alloy is also used for the modification of non-metallic inclusions. Calcium Silicon is used to control the shape, size and distribution of oxide and sulphide inclusions improving fluidity, machinability, ductility, and impact properties of the steel product.

Product Descriptions:

Ferro boron is (CAS Registry Number 11108–67-1) is a ferroalloy of iron and boron with boron content between 17.5 and 20%.

It is manufactured either by carbothermic reduction of boric acid in an electric arc furnace together with carbon steel, or by the aluminothermic reduction of boric acid in the presence of iron.

Ferro boron is added to C-Mn and other low alloy steels to improve hardenability (see Boron steel), and can also act as a nitrogen scavenger in steel, and in the production of NdFeB magnets.

Product Descriptions:

The alloy is produced by heating a mixture of molybdenum(VI) oxide MoO3, aluminium, and iron. The oxide and the aluminium combine via an aluminothermic reaction to give molybdenum in situ. The ferro molybdenum can be purified by electron beam melting or used as it is. For alloying with steel the ferro molybdenum is added to molten steel before casting.

Product Descriptions:

Ferro phosphorus is a ferroalloy, an alloy of iron and phosphorus. It contains high proportion of iron phosphides, Fe2P and Fe3P. Its CAS number is 8049-19-2. The usual grades contain either 18 or 25% of phosphorus.[1] It is a gray solid material with melting point between 1050-1100 °C. It may liberate phosphine in contact with water. Very fine powder can be combustible.

Ferro phosphorus is used in metallurgy as a source of phosphorus for alloying, for deoxidizing the melt and for removal of unwanted compounds into slag.

Ferro phosphorus is a byproduct of phosphorus production in submerged-arc furnaces from apatites, by their reduction with carbon. It is formed from the iron oxide impurities.

Addition of ferro phosphorus is used to produce powder metallurgy (P/M) steels with favorable magnetic properties, e.g. high saturation induction. Iron phosphide acts here as a solid solution hardener and a sintering aid. Usually about 0.45 w/o of phosphorus is added to iron; higher amount can improve magnetic properties but at above about 0.8 w/o the process parameters have to be too tightly controlled to prevent phosphorus segregation on grain boundaries and resulting excessive brittleness.

Product Descriptions:

Ferro titanium is a ferroalloy, an alloy of iron and titanium with between 10–20% iron and 45–75% titanium and sometimes a small amount of carbon. It is used in steelmaking as a cleansing agent for iron and steel; the titanium is highly reactive with sulfur, carbon, oxygen, and nitrogen, forming insoluble compounds and sequestering them in slag, and is therefore used for deoxidizing, and sometimes for desulfurization and denitrogenation. In steelmaking the addition of titanium yields metal with finer grain structure. Ferro titanium can be manufactured by mixing titanium sponge and scrap with iron and melting them together in an induction furnace.[1] Ferro titanium powder can be also used as a fuel in some pyrotechnic compositions.

Product Descriptions:

Ferro vanadium (FeV) is an alloy formed by combining iron and vanadium with a vanadium content range of 35–85%. The production of this alloy results in a grayish silver crystalline solid that can be crushed into a powder called "ferro vanadium dust".[2] Ferrovanadium is a universal hardener, strengthener and anti-corrosive additive for steels like high-strength low-alloy steel, tool steels, as well as other ferrous-based products. It has significant advantages over both iron and vanadium individually. Ferro vanadium is used as an additive to improve the qualities of ferrous alloys. One such use is to improve corrosion resistance to alkaline reagents as well as sulfuric and hydrochloric acids. It is also used to improve the tensile strength to weight ratio of the material. One application of such steels is in the chemical processing industry for high pressure high throughput fluid handling systems dealing with industrial scale sulfuric acid production. It is also commonly used for hand tools e.g. spanners (wrenches), screwdrivers, ratchets, etc.