Our range of Stainless Steel Scrap is widely used for manufacturing of various stainless steel products including pharmaceutical, medical, aerospace and other consumer products. We offer a wide range of stainless steel scrap that is available in 304, 316, 310 and 410 grades. The entire range of these scrap is procured from reliable vendors of the industry, who have rich industrial experience of metal industry.
Our range of Stainless Steel Scrap is widely used for manufacturing of various stainless steel products including pharmaceutical, medical, aerospace and other consumer products. We offer a wide range of stainless steel scrap that is available in 304, 316, 310 and 410 grades. The entire range of these scrap is procured from reliable vendors of the industry, who have rich industrial experience of metal industry.
Manganese (M) : 99.7% Min
Nitrogen (N) : 0.04% Max
Carbon (C) : 0.05% Max
Silicon (Si) : 0.005% Max
Phosphurus (P) : 0.005% Max
Sulphur (S) : 0.03% Max
Manganese (M) : 99.7% Min
Nitrogen (N) : 0.04% Max
Carbon (C) : 0.05% Max
Silicon (Si) : 0.005% Max
Phosphurus (P) : 0.005% Max
Sulphur (S) : 0.03% Max
This refractory mix is high alumina mix where in predominant aggregate component of alumina imparts a strong skeleton aggregate structure of superior uniform heat stability. The refractory mix is characterized by an ability to withstand corrosive-erosive attack of molten metal's and their acids, semi basic and basic slags during repeated exposure thereto, together with excellent volume stability, superior structure heat stability, low apparent porosity, a high contact angle with molten steel and strong abrasion resistance matrix.
This refractory mix is high alumina mix where in predominant aggregate component of alumina imparts a strong skeleton aggregate structure of superior uniform heat stability. The refractory mix is characterized by an ability to withstand corrosive-erosive attack of molten metal's and their acids, semi basic and basic slags during repeated exposure thereto, together with excellent volume stability, superior structure heat stability, low apparent porosity, a high contact angle with molten steel and strong abrasion resistance matrix.
Fixed Carbon : 72 % MIN
Ash : 20 - 22% MAX
Volatile Matter : 04 - 4.5%
Sulphur : 0.5 % Max
Other Minerals : 1.0 % Max
Low Ash Metallurgical Coke is designed for the requirement of Blast furnace, Ferro alloys Industries, Foundries, Zinc melters and has advantages like consistency in quality, sizing and uniform temperature. Thereby reducing cold spots and metal wastage and is consumed less per ton of output.
Fixed Carbon : 72 % MIN
Ash : 20 - 22% MAX
Volatile Matter : 04 - 4.5%
Sulphur : 0.5 % Max
Other Minerals : 1.0 % Max
Low Ash Metallurgical Coke is designed for the requirement of Blast furnace, Ferro alloys Industries, Foundries, Zinc melters and has advantages like consistency in quality, sizing and uniform temperature. Thereby reducing cold spots and metal wastage and is consumed less per ton of output.
Fosterite based ramming mass for making laddles of foundry. Diluted sodium silicate to be used as binder before pre-heating.
Method to use: After mixing 4-5% of diluted sodium silicate, good compact ramming is required to be done, talking special care of the impact area which is the bottom. After completing the ramming process slow pre-heating is requied to be done for 3-5 hours (depending on the capacity of the laddle). There after laddle is to be kept in red hot condition for one hour.
Fosterite based ramming mass for making laddles of foundry. Diluted sodium silicate to be used as binder before pre-heating.
Method to use: After mixing 4-5% of diluted sodium silicate, good compact ramming is required to be done, talking special care of the impact area which is the bottom. After completing the ramming process slow pre-heating is requied to be done for 3-5 hours (depending on the capacity of the laddle). There after laddle is to be kept in red hot condition for one hour.
Chrome enriched magnesite based ramming mass for making ladles of foundry.
Plain water to be used as binder before pre-heating.
Method to use: After mixing 3-4% of plain water, good compact ramming is required to be done, talking special care of the impact area which is the bottom. After completing the ramming process slow pre-heating is requied to be done for 3-5 hours (depending on the capacity of the laddle). There after laddle is to be kept in red hot condition for one hour.
Chrome enriched magnesite based ramming mass for making ladles of foundry.
Plain water to be used as binder before pre-heating.
Method to use: After mixing 3-4% of plain water, good compact ramming is required to be done, talking special care of the impact area which is the bottom. After completing the ramming process slow pre-heating is requied to be done for 3-5 hours (depending on the capacity of the laddle). There after laddle is to be kept in red hot condition for one hour.
Magnesite based ramming mass for making the top & spout of induction furnace, with special bonds to form a strong chemical bond with Sodium Silicate.
Method to use: Material is to be mixed homogeneous with 4-5% diluted Sodium Silicate & water. Then after it is properly applied on the top and spout.
Magnesite based ramming mass for making the top & spout of induction furnace, with special bonds to form a strong chemical bond with Sodium Silicate.
Method to use: Material is to be mixed homogeneous with 4-5% diluted Sodium Silicate & water. Then after it is properly applied on the top and spout.
This is a magnesite based ramming mix for medium high frequency induction furnace, melting various types of ferrous non-ferrous metals. Processing of the raw material is done with modern machineries to avoid any sort of contamination. Tailor made material is manufactured keeping in view the size of the crucible and type of the metal.
This is a magnesite based ramming mix for medium high frequency induction furnace, melting various types of ferrous non-ferrous metals. Processing of the raw material is done with modern machineries to avoid any sort of contamination. Tailor made material is manufactured keeping in view the size of the crucible and type of the metal.
Material is to be used for the patching of worn out parts of the crucible. Cracks in the lining can also be filled with the same.
Method to use: Material is to be mixed with 5-6% 1:1 solution of Foundry Grade Sodium Silicate and water. Homogeneous mixing is required to be done. Area to be patched should be neatly dressed off slag, for better performance.
Material is to be used for the patching of worn out parts of the crucible. Cracks in the lining can also be filled with the same.
Method to use: Material is to be mixed with 5-6% 1:1 solution of Foundry Grade Sodium Silicate and water. Homogeneous mixing is required to be done. Area to be patched should be neatly dressed off slag, for better performance.
Material is to be used for giving coating to water cooled copper coil.
Method to use: Homogeneous mixing is required to be done with 6-8% of plain water in order to get material in the form of paste. It is to be applied on coil. Drying can be done by putting 500 1000 watt bulbs insite the crucible.
Material is to be used for giving coating to water cooled copper coil.
Method to use: Homogeneous mixing is required to be done with 6-8% of plain water in order to get material in the form of paste. It is to be applied on coil. Drying can be done by putting 500 1000 watt bulbs insite the crucible.
We are one of the leading company in trading of quality hms scraps (industrial heavy melting scraps) that finds wide application in numerous industries. Hms 1 & 2 scrap
We are one of the leading company in trading of quality hms scraps (industrial heavy melting scraps) that finds wide application in numerous industries. Hms 1 & 2 scrap
Super purity high alumina mortars are being produced at our plant.
These mortars possess our brand name DI-90-K and DI-95-H and are manufactured using high purity calcined, reactive alumina powder and green chrome oxide.
Salient Features
Highest Purity
Superior Resistance to Temperature
Resist Fluctuations of Temperature
Suitable for use in reducing atmospheres
Super purity high alumina mortars are being produced at our plant.
These mortars possess our brand name DI-90-K and DI-95-H and are manufactured using high purity calcined, reactive alumina powder and green chrome oxide.
Salient Features
Highest Purity
Superior Resistance to Temperature
Resist Fluctuations of Temperature
Suitable for use in reducing atmospheres
V : 50% (Approx)
C : 0.26% (Approx)
Si : 1% to 2% (Approx)
P : 0.017% (Approx)
S : 0.021% (Approx)
Mn : 0.21% (Approx)
Al : 0.61% (Approx)
Fe : 13.39% (Approx)
Cu : 0.17% (Approx)
As : 0.008% (Approx)
Size :10-50mm (Approx)
V : 50% (Approx)
C : 0.26% (Approx)
Si : 1% to 2% (Approx)
P : 0.017% (Approx)
S : 0.021% (Approx)
Mn : 0.21% (Approx)
Al : 0.61% (Approx)
Fe : 13.39% (Approx)
Cu : 0.17% (Approx)
As : 0.008% (Approx)
Size :10-50mm (Approx)
High Carbon Medium Carbon Low Carbon
Mn : 70 - 75 % 70 - 75 % 70 - 75 %
C : 6 - 8% Max 1 - 2% Max 0.1% Max
P : 0.35% Max 0.35% Max 0.35% Max
S : 0.35% Max 0.35% Max 0.35% Max
Si : 3 - 4 % 3 - 4 % 1.5%
Size : 20 - 150 mm 20 - 150 mm 20 - 150 mm
High Carbon Medium Carbon Low Carbon
Mn : 70 - 75 % 70 - 75 % 70 - 75 %
C : 6 - 8% Max 1 - 2% Max 0.1% Max
P : 0.35% Max 0.35% Max 0.35% Max
S : 0.35% Max 0.35% Max 0.35% Max
Si : 3 - 4 % 3 - 4 % 1.5%
Size : 20 - 150 mm 20 - 150 mm 20 - 150 mm
High Carbon Low Carbon
Cr : 60 % 60 %
Si : 3 - 3.5% Max 1.5% Max
P : 0.35% Max 0.35% Max
S : 0.35% Max 0.35% Max
C : 6 - 8 % 0.03%
Size : 20 - 150 mm 20 - 150 mm
High Carbon Low Carbon
Cr : 60 % 60 %
Si : 3 - 3.5% Max 1.5% Max
P : 0.35% Max 0.35% Max
S : 0.35% Max 0.35% Max
C : 6 - 8 % 0.03%
Size : 20 - 150 mm 20 - 150 mm
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