Trading Division
Ferrosilicon
Ferrosilicon
Ferro Silicon is an alloy of silicon and iron. Silicon acts as a strong steel oxidant. Used primarily in special steels and in small quantities in mild steel. Ferro silicon is also used for manufacture of silicon, corrosion-resistant and high-temperature resistant ferrous silicon alloys, and silicon steel for electromotors and transformer cores.
Key Features:
Precise composition
High purity
Rigidity
Key Features:
Precise composition
High purity
Rigidity
Ferro Silicon Magnesium
Ferro Silicon Magnesium
Ferro Silicon Magnesium Alloys are master alloys of magnesium with Iron And Silicon. They facilitate small additions of Magnesium to iron, required to transform graphite flakes to spheroids.
Application :Nodulisation is a process of controlling the structure and properties by changing the graphite shape from flakes to spheroidal in cast iron during solidification. A noduliser is a material which contains spheroidal graphite forming elements such as Mg, Ce, Ca, Ba, etc.
Application :Nodulisation is a process of controlling the structure and properties by changing the graphite shape from flakes to spheroidal in cast iron during solidification. A noduliser is a material which contains spheroidal graphite forming elements such as Mg, Ce, Ca, Ba, etc.
FeSi Inoculants
FeSi Inoculants
Inoculant - Ferro Silicon Barium (High and standard Barium)
Application :
Inoculation is a process of controlling the structure and properties of cast iron by increasing the number of nucleation events during solidification. An inoculant is a material added to the hot metal just prior to casting which provides as suitable phase for nucleation of graphite during subsequent cooling process. The objective of inoculation is to provide enough nucleation sites for the carbon to precipitate as graphite instead of iron carbide(cementite, Fe3C)
CFC supplies inoculants for the production of both ductile iron and cast iron.
Application :
Inoculation is a process of controlling the structure and properties of cast iron by increasing the number of nucleation events during solidification. An inoculant is a material added to the hot metal just prior to casting which provides as suitable phase for nucleation of graphite during subsequent cooling process. The objective of inoculation is to provide enough nucleation sites for the carbon to precipitate as graphite instead of iron carbide(cementite, Fe3C)
CFC supplies inoculants for the production of both ductile iron and cast iron.
Ferro Manganese
Ferro Manganese
Ferro Manganese is primarily an alloy of manganese and iron. It contains a high content of manganese and used in steel products wherein silicon content needs to be controlled at low levels. It is mainly used in the silico manganese production of flat steel, manganese-rich steel and stainless steel products.
Configuration: Low P, Low Ti.
Key Features:
Impeccable chemical composition
Free from impurities
Corrosion proof
Fine anti-oxidant characteristics
Low melting point
Sturdiness
Ferro manganese is used mainly to counteract the bad effects of sulfur. It also acts as a deoxidizer and combines with sulfur, thereby improving the hot-working properties of the product. It imparts metallurgical properties such as increased strength, hardness toughness and hardenability.
Typical Applications
Used in the manufacture of steel and to a lesser extent other metal alloys.
FeMn powder= welding industry
FeMn lump= steel industry
Configuration: Low P, Low Ti.
Key Features:
Impeccable chemical composition
Free from impurities
Corrosion proof
Fine anti-oxidant characteristics
Low melting point
Sturdiness
Ferro manganese is used mainly to counteract the bad effects of sulfur. It also acts as a deoxidizer and combines with sulfur, thereby improving the hot-working properties of the product. It imparts metallurgical properties such as increased strength, hardness toughness and hardenability.
Typical Applications
Used in the manufacture of steel and to a lesser extent other metal alloys.
FeMn powder= welding industry
FeMn lump= steel industry
Ferro Chrome
Ferro Chrome
The two main products of chromite refining are Ferro Chrome and Chromium Metal. For the production of Ferro Chrome the chromite ore is reduced, usually by coal and coke in a high temperature reaction in an electric arc furnace to form the iron-chrome alloy. For production of pure chrome the iron has to be separated from the chrome in a two-step roasting and leaching process.
Chromium metal is of high value for its high corrosion resistance and hardness. A major development in steel production was the discovery that steel could be made highly resistant to corrosion and discoloration by adding metallic chromium to form stainless steel. Stainless steel and chrome plating (electroplating with chromium) together comprise 85% of the commercial use.
Ferrochromium alloy is commercially produced from chromite by silicothermic or aluminothermic reactions and chromium metal by roasting and leaching processes followed by reduction with carbon and then aluminium. Few types :
Low carbon Ferro Chrome
Extra Low Carbon Ferro Chrome
Medium Carbon Ferro Chrome
High Carbon Ferro Chrome
Nitrided Ferro Chrome
Chromium metal is of high value for its high corrosion resistance and hardness. A major development in steel production was the discovery that steel could be made highly resistant to corrosion and discoloration by adding metallic chromium to form stainless steel. Stainless steel and chrome plating (electroplating with chromium) together comprise 85% of the commercial use.
Ferrochromium alloy is commercially produced from chromite by silicothermic or aluminothermic reactions and chromium metal by roasting and leaching processes followed by reduction with carbon and then aluminium. Few types :
Low carbon Ferro Chrome
Extra Low Carbon Ferro Chrome
Medium Carbon Ferro Chrome
High Carbon Ferro Chrome
Nitrided Ferro Chrome
Silicomanganese (SIMN)
Silicomanganese (SIMN)
Application:
Silico Manganese is used as a deoxidizer and an alloying element in steel. The standard grade Ferro Silico Manganese contains 14 to 16% of silicon, 65 to 68% of manganese and 250% of carbon. Special grades with up to 30% Si are used in the manufacture of stainless steel. Ferro Silico Manganese can be used as a substitute for Ferro Silicon and Ferro Manganese when added to make different types of steel. Both silicon and manganese have an important influence on the properties of steel, depending on the amount added and the combined effect with other alloying elements. Silicon and manganese have a strong affinity for oxygen, and will act as deoxidizers. Deoxidation with SiMn results in cleaner steel, as the liquid manganese silicate formed coagulates and separates easier from the melt, compared to solid SiO2 formed during FeSi deoxidation. Use of Ferro Silico Manganese adds less phosphorus, carbon, and nitrogen to steel compared to standard FeSi 75 plus HC FeMn.
Silico Manganese is used as a deoxidizer and an alloying element in steel. The standard grade Ferro Silico Manganese contains 14 to 16% of silicon, 65 to 68% of manganese and 250% of carbon. Special grades with up to 30% Si are used in the manufacture of stainless steel. Ferro Silico Manganese can be used as a substitute for Ferro Silicon and Ferro Manganese when added to make different types of steel. Both silicon and manganese have an important influence on the properties of steel, depending on the amount added and the combined effect with other alloying elements. Silicon and manganese have a strong affinity for oxygen, and will act as deoxidizers. Deoxidation with SiMn results in cleaner steel, as the liquid manganese silicate formed coagulates and separates easier from the melt, compared to solid SiO2 formed during FeSi deoxidation. Use of Ferro Silico Manganese adds less phosphorus, carbon, and nitrogen to steel compared to standard FeSi 75 plus HC FeMn.
Carbon Raiser
Carbon Raiser
CFC offers The Most Economical High Quality Carbon Additive in the Market.
products offer the following advantages:
High Carbon Recovery ,Rapid Dissolution
Consistency
Low Ashgroup-2
Low Sulfur ,Low Nitrogen, Low Hydrogen
Reliability
Economical Savings
Reduced Carbon Consumption, Tap-to-Tap Time, and Scrap Rate
We can offer a wide range of carbon raisers based on customer requirements.
products offer the following advantages:
High Carbon Recovery ,Rapid Dissolution
Consistency
Low Ashgroup-2
Low Sulfur ,Low Nitrogen, Low Hydrogen
Reliability
Economical Savings
Reduced Carbon Consumption, Tap-to-Tap Time, and Scrap Rate
We can offer a wide range of carbon raisers based on customer requirements.
Melting Furnaces and other Equipments
Melting Furnaces and other Equipments
Our services include but not limited to:
Induction Melting Systems,
IGBT Controlled Melting Systems,
Induction Heating Systems,
Steel Mill Solutions,
Non-metal Melting Solutions
Induction Melting Systems,
IGBT Controlled Melting Systems,
Induction Heating Systems,
Steel Mill Solutions,
Non-metal Melting Solutions
Foundries Consumables (Crudibles)
Foundries Consumables (Crudibles)
CFC provides crucibles that ideal for melting non-ferrous metals such as: aluminum, copper, zamak, brass, bronze, gold and silver.
Refractories
Refractories
CFC provides a wide range of refractory masses and precast shapes for the Iron and Steel Industry through it’s reliable partner INSERTEC co which owns a Quartzite mine, where high quality mineral is extracted.
The products range include but not limited to the following industries:
CFC can provide its customers with their refractory needs for the below industries:
Iron foundry
Steel foundry
Aluminum foundry
Cement plants
Frites and enamels
Heat treatment
Steel works
Non ferrous foundry
Glass industry
The products range include but not limited to the following industries:
CFC can provide its customers with their refractory needs for the below industries:
Iron foundry
Steel foundry
Aluminum foundry
Cement plants
Frites and enamels
Heat treatment
Steel works
Non ferrous foundry
Glass industry
Ceramic Filters
Ceramic Filters
Ceramic foam is a new industrial ceramic products with low bulk density (0.25 ~ 0.65) g/cm3, high porosity (60% ~ 90%), and three-dimensional reticulated structure. As ceramic foam has excellent properties such like: high temperature resistance, strong chemical corrosion resistance, and large surface area as a result of high porosity, it is widely used in molten metal filtration to remove undesirable nonmetallic inclusions in the melt.
The merits of ceramic foam filter include:
Reduce gas and inclusions that are contained in the casting, reduce the turbulence level of molten metal when filling the mold, reduce surface defects in castings, and significantly reduce the rejection rate of casting
Increase the compressive sealing of casting, increase elongation and tensile strength of casting, improved surface finish of casting, improve the mobility of molten metal, increase the filling capacity and the feeding capacity of melt.
Simplify the casting system, reduce the length of the lateral flow channel, improve casting yield.
Reduce the processing time and tool abrasion, improve surface quality of casting.
Ceramic foam possesses high mechanical strength, chemical stability, high resistance to thermal shock and liquid metal flow shock even under high temperature environment. No slag or broken in working process, to ensure the quality and stable chemical composition of the molten metal.
Has a large and stable metal flow, even if the high content of inclusions in molten metals, ceramic foam filter will not be plugged high dimensional accuracy, can be automatically placed in production line.
We can offer variety of graded upon request.
The merits of ceramic foam filter include:
Reduce gas and inclusions that are contained in the casting, reduce the turbulence level of molten metal when filling the mold, reduce surface defects in castings, and significantly reduce the rejection rate of casting
Increase the compressive sealing of casting, increase elongation and tensile strength of casting, improved surface finish of casting, improve the mobility of molten metal, increase the filling capacity and the feeding capacity of melt.
Simplify the casting system, reduce the length of the lateral flow channel, improve casting yield.
Reduce the processing time and tool abrasion, improve surface quality of casting.
Ceramic foam possesses high mechanical strength, chemical stability, high resistance to thermal shock and liquid metal flow shock even under high temperature environment. No slag or broken in working process, to ensure the quality and stable chemical composition of the molten metal.
Has a large and stable metal flow, even if the high content of inclusions in molten metals, ceramic foam filter will not be plugged high dimensional accuracy, can be automatically placed in production line.
We can offer variety of graded upon request.
Steel Shots
Steel Shots
CFC can offer a range of low carbon steel shots .
Why Low Carbon?
Low carbon and high manganese steel shot have high impact absorption capacity, impacts are distributed uniformly throughout the shot.
During shot blasting operations, low carbon steel shot is peeled down into thin layers similar to the layers of onions for up to 80 percent of their life due to wear, and are only broken into small pieces due to fatigue of the material. Machine and blade erosion are also significantly reduced as they are divided into lesser and smaller parts.
High carbon steel shot particles however are broken into large and angular pieces in a short time due to the crack structure formed during production. With this feature, the machine causes high extra costs on turbine equipment and filters.
Surface cracks are not seen in low carbon shot as in high carbon shot. Cracks reduce the life of the shot. Due to the high manganese content, the low carbon steel shot hardens up to 46-49 HRC in the blasting machine in a very short time. Therefore, it has a better cleaning effect than high carbon material.
Why Low Carbon?
Low carbon and high manganese steel shot have high impact absorption capacity, impacts are distributed uniformly throughout the shot.
During shot blasting operations, low carbon steel shot is peeled down into thin layers similar to the layers of onions for up to 80 percent of their life due to wear, and are only broken into small pieces due to fatigue of the material. Machine and blade erosion are also significantly reduced as they are divided into lesser and smaller parts.
High carbon steel shot particles however are broken into large and angular pieces in a short time due to the crack structure formed during production. With this feature, the machine causes high extra costs on turbine equipment and filters.
Surface cracks are not seen in low carbon shot as in high carbon shot. Cracks reduce the life of the shot. Due to the high manganese content, the low carbon steel shot hardens up to 46-49 HRC in the blasting machine in a very short time. Therefore, it has a better cleaning effect than high carbon material.
AlTi5B1(Coil ,or As required by end user)
AlTi5B1(Coil ,or As required by end user)
In cast house applications, the control of grain size is absolutely essential in maintaining product consistency and quality, reducing costs, and maintaining high levels of productivity. The controlled addition of AMG Aluminum’s titanium boron aluminum grain refiners to molten aluminum releases nucleant particles that promote equiaxed, fine grain structures throughout the cast alloy, thus avoiding formation of columnar crystals. Casting speed can also be increased. The addition of a titanium-boron-aluminium grain refiner improves homogeneity and allows for a uniform distribution of alloying elements, reduces porosity, eliminates hot tearing in cast structures, improves responsiveness to subsequent heat treatment, and enhances mechanical properties and machinability in the fabrication process.
Si Metal
Si Metal
Silicon in the form of a crystalline solid in blue-grey metallic color is rarely found naturally. It is rather can be found in planets, meteorites and dusts in silicon dioxide forms. Silicon is a second most abundant element that can be found in the Earth's crust, followed by oxygen. When in its elementary form, its crystal structure is similar to that of diamond. This utility element can form semi-conducting crystals for several applications. This semi-conductive metal is useful in manufacturing steel, microchips and solar cells. It contracts in its liquid state, while expands when solidifies. It forms crystal structure similar to diamond's when crystallized. The atomic structure of this metal makes it ideal to be used in electronics. Silicon readily bond with other elements, because of the four valence electrons.
Applications:
As silicon is available in abundance and in several forms, its many applications is evident. Polycrystalline silicon is the latest application of silicon that is used in the form of wafer. It basically used in thin-film solar cells and PV system as semi-conductors. It also finds use as power transistor and semiconductor in generic field of electronics. It is a key constituent in products, like cement, electrical steel, ceramic, concrete and glass. Silicon is widely used for aluminum-silicon (AlSi) alloys for cast components used in the automotive industry. It can form ferro-silicon (FeSi) when added to molten cast iron. By consumption, aluminum industry leads, leaving behind chemical and solar industries. It is possible to use gallium-arsenide (GeAs) or germanium (Ge) besides silicon in semiconductors and infrared applications. It's metallic form called ferro silicon is widely used as a deoxidizing agent in the carbon and stainless steel production. Ferro silicon is highly demanded and used in steel smelting. Other than steel making, ferro silicon can be used to refine high purity magnesium, and produce ductile iron and magnesium ferro silicon. It can also make silicon steel and ferrous silicon alloys that are resistant to corrosion and heat. Metallurgical silicon is used as an alloying agent in aluminum casting and resultant aluminum-silicon (Al-Si) is used to make light in wight and strong car components that are better than components cast from pure aluminum. Chemical industry uses metallurgical silicon in making fumed silica, silanes and silicone.
Applications:
As silicon is available in abundance and in several forms, its many applications is evident. Polycrystalline silicon is the latest application of silicon that is used in the form of wafer. It basically used in thin-film solar cells and PV system as semi-conductors. It also finds use as power transistor and semiconductor in generic field of electronics. It is a key constituent in products, like cement, electrical steel, ceramic, concrete and glass. Silicon is widely used for aluminum-silicon (AlSi) alloys for cast components used in the automotive industry. It can form ferro-silicon (FeSi) when added to molten cast iron. By consumption, aluminum industry leads, leaving behind chemical and solar industries. It is possible to use gallium-arsenide (GeAs) or germanium (Ge) besides silicon in semiconductors and infrared applications. It's metallic form called ferro silicon is widely used as a deoxidizing agent in the carbon and stainless steel production. Ferro silicon is highly demanded and used in steel smelting. Other than steel making, ferro silicon can be used to refine high purity magnesium, and produce ductile iron and magnesium ferro silicon. It can also make silicon steel and ferrous silicon alloys that are resistant to corrosion and heat. Metallurgical silicon is used as an alloying agent in aluminum casting and resultant aluminum-silicon (Al-Si) is used to make light in wight and strong car components that are better than components cast from pure aluminum. Chemical industry uses metallurgical silicon in making fumed silica, silanes and silicone.
Mg Ingots 99.9 %
Mg Ingots 99.9 %
Elemental magnesium is a gray-white lightweight metal, two-thirds the density of aluminum. Magnesium has the lowest melting (923 K (1,202° F)) and the lowest boiling point 1,363 K (1,994° F) of all the alkaline earth metals.
Pure magnesium is brittle and easily fractures along shear bands. It becomes much more ductile when alloyed with small amount of other metals, such as 1% aluminum.
Ductility of polycrystalline magnesium can also be significantly improved by reducing its grain size to ca. 1 micron or less.
Magnesium is a silver-white metallic element and the lightest of all structural metals. Magnesium is available in two principal forms, pure and alloy. Pure magnesium in unwrought form contains at least 99.8 percent magnesium by weight. Magnesium Ingots can be used in the production of magnesium alloy, as well as for use in chemical industrial, military industrial and meter instrument manufacture, etc.
Magnesium is used in super-strong, lightweight materials and alloys. For example, when infused with silicon carbide nanoparticles, it has extremely high specific strength. Magnesium, being readily available and relatively nontoxic, has a variety of uses:
As a reducing agent to separate uranium and other metals from their salts.
As a sacrificial (galvanic) anode to protect boats, underground tanks, pipelines, buried structures, and water heaters.
Alloyed with zinc to produce the zinc sheet used in photoengraving plates in the printing industry, dry-cell battery walls, and roofing.[35]
As a metal, this element's principal use is as an alloying additive to aluminium with these aluminium-magnesium alloys being used mainly for beverage cans, sports equipment such as golf clubs, fishing reels, and archery bows and arrows.
Pure magnesium is brittle and easily fractures along shear bands. It becomes much more ductile when alloyed with small amount of other metals, such as 1% aluminum.
Ductility of polycrystalline magnesium can also be significantly improved by reducing its grain size to ca. 1 micron or less.
Magnesium is a silver-white metallic element and the lightest of all structural metals. Magnesium is available in two principal forms, pure and alloy. Pure magnesium in unwrought form contains at least 99.8 percent magnesium by weight. Magnesium Ingots can be used in the production of magnesium alloy, as well as for use in chemical industrial, military industrial and meter instrument manufacture, etc.
Magnesium is used in super-strong, lightweight materials and alloys. For example, when infused with silicon carbide nanoparticles, it has extremely high specific strength. Magnesium, being readily available and relatively nontoxic, has a variety of uses:
As a reducing agent to separate uranium and other metals from their salts.
As a sacrificial (galvanic) anode to protect boats, underground tanks, pipelines, buried structures, and water heaters.
Alloyed with zinc to produce the zinc sheet used in photoengraving plates in the printing industry, dry-cell battery walls, and roofing.[35]
As a metal, this element's principal use is as an alloying additive to aluminium with these aluminium-magnesium alloys being used mainly for beverage cans, sports equipment such as golf clubs, fishing reels, and archery bows and arrows.