TH39358A - Methods for producing steel for large formwork - Google Patents

Abstract

DC60 This invention relates to a method for producing steel for large formwork. According to this invention This steel is obtained by melting in an electric furnace. Continue with this process Secondary metallurgical operations in the heating chamber After this process Will eliminate gas under Less than 1 torr under vacuum, which is in fact equal to 0.2 torr of the mixture containing The following elements: 1 to 3% manganese, silicon less than or equal to 0.400%, phosphorus less than or equal to 0.015%, chromium 1.50 to 3.5%, molybdenum 0.25 to 1%, niobium 0.100 - 0.250%, titanium or zirconium, if required, 100 to 300 ppm Copper less than or equal to 0.300% Nickel less than or equal 0.300% Nitrogen less than or equal 80 ppm Oxygen less than or equal 80 ppm Calcium less than or equal 30 ppm Boron 15 to 50 ppm Carbon 0.10 to 0.25% Sulfur 0.050% aluminum less than or equal to 250 ppm This invention relates to a method for producing steel for large formwork. According to this invention This steel is obtained by melting in an electric furnace. Continue with this process Secondary metallurgical operations in the heating chamber After this process Will eliminate gas under Less than 1 torr under vacuum, which is in fact equal to 0.2 torr of the mixture containing The following elements: manganese 1 to 3% silicon <= (less than / equal) 0.400% phosphorus &lt; = (less than / equal) 0.015% chromium 1.50 to 3.5% molybdenum 0.25 to 1% niobium 0.100 -0.250% titanium or zirconium if required 100 to 300 ppm copper &lt; = (less than / equal) 0.300% nickel = (less than / equal) 0.300% nitrogen <= (less than / equal) 80 ppm Oxygen <= (less than / equal to) 80 ppm Calcium &lt; = (less than / equal) 30 ppm Boron 15 to 50 ppm Carbon 0.10 to .25% Sulfur 0.050% Aluminum <= (less than / equal) 250 ppm

Claims (6)

1.Methods for producing steel for large formwork Which has the characteristics It is steel obtained by annealing in an electric furnace followed by a secondary metallurgical process in a heating crucible. And that process will be followed by Vacuum gas removal at a pressure of less than 1 torr and equal to 0.2 torr of the containing mixture. Composition by weight as follows: 1 to 3% manganese, silicon <= (less than / equal) 0.400% phosphorus <= (less than / equal) 0.015% chromium 1.50 to 3.5% molybdenum 0.25 to 1% Niobium 0.100-0.250% titanium or zirconium if required 100 to 300 ppm copper <= (less than / equal to) 0.300% nickel <0.300% nitrogen <= (less than / equal) 80 ppm oxygen <= ( Less than / equal) 80 ppm Calcium <= (less than / equal) 30 ppm Boron 15 to 50 ppm Carbon 0.10 to 0.25% Sulfur 0.050% Aluminum <= (less than / equal) 250 ppm Iron rest And impurities that are characteristic of steel production 2. Method according to claim 1, which has the characteristics of the derived ingot, must be degassed for re-smelting. With consumable electrodes Under vacuum Or under slag, metal ingots will be used Are consumable electrodes 3. Method according to claim 2, which has the characteristics of ingots obtained by gas removal. Will be done the process First smelt With consumable electrodes Under vacuum and a second re-melting process with consumable electrodes could be depleted. Under slag Where the metal rod can be used like a consumable electrode 4. Method for any of the foregoing claims Where the peculiarities of shaping were performed by mechanical-thermal transformations. 5. Steel for large formwork. Which has the following characteristics of the composition by weight: 1 to 3% manganese; silicon <= (less than / equal) 0.400% phosphorus <= (less than / equal) 0.015% chromium 1.50 to 3.5% molybdenum. 0.25 to 1% niobium 0.100-0.250% titanium or zirconium if required 100 to 300 ppm copper <= (less than / equal) 0.300% nickel &lt; = (less than / equal) 0.300% nitrogen <= (less Over / equal) 80 ppm oxygen <= (less than / equal to) 80 ppm calcium <= (less than / equal) 30 ppm boron 15 to 50 ppm carbon 0.10 to 0.25% sulfur 0.0250% aluminum <= ( Less than / equal to) 250 ppm, the rest is iron And impurities that are characteristic of steelmaking 6. Steel according to claim 5, which has the following characteristics of composition by weight: 1.50-2% manganese, silicon 0.050-0.150% phosphorus <= (less than / equal) 0.008% chromium 2 to 2.40% molybdenum. Num 0.35 to 0.50% Niobium 0.100-0.150% Titanium or Zirconium if required 100 to 200 ppm Copper <= (less than / equal to) 0.100% Nickel <= (less than / equal) 0.200% Nitrogen &lt; = (Less than / equal to) 30 ppm oxygen <= (less than / equal) 20 ppm Calcium 5 to 20 ppm Boron 20 to 30 ppm Carbon 0.15 to 0.20% Sulfur 0.005% Aluminum <= (less than / equal) 40 ppm The rest is iron And impurities that are characteristic of steelmaking