Methods, compositions and structures for advanced design low alloy nitrogen steels

What is claimed is: 1. A low alloy high nitrogen steel comprising iron and, by weight: 0.14-0.60% nitrogen (N); 0.08-0.28% carbon (C); 0.10-2.20% nickel (Ni); 0.25-2.00% manganese (Mn); 1.20-2.70% chromium (Cr); 0.45-1.50% tungsten (W); not more than 0.05% molybdenum (Mo); not more than 0.02% vanadium (V); not more than 0.60% silicon (Si); not more than 0.10% copper (Cu); not more than 0.02% titanium (Ti); not more than 0.02% niobium (Nb); not more than 0.008% aluminum (Al); and not more than 0.02% of any other element with not more than 0.10% total other elements, wherein cobalt (Co) is substitutable for any part of the nickel. 2. The steel of claim 1 , further comprising, by weight: not more than 0.008% sulfur; not more than 0.015% phosphorus; not more than 40 ppm oxygen; not more than 4 ppm hydrogen; not more than 0.005% antimony; not more than 0.005% arsenic; and not more than 0.005% tin. 3. The steel of claim 1 , wherein said steel comprises a microstructure comprising tempered martensite with, or without bainite, preferred minimal amounts of S, P, As, Sb, Sn, oxygen and hydrogen impurities, and preferred shape control of any S constituents. 4. The steel of claim 1 , further comprising, by weight: 0.14-0.20% nitrogen; 0.14-0.18% carbon; 1.00-1.80% nickel; 1.00-1.70% manganese; 1.30-1.70% chromium; and 0.45-0.90% tungsten. 5. The steel of claim 1 , further comprising, by weight: 0.16-0.21% nitrogen; 0.16-0.20% carbon; 0.60-2.20% nickel; 0.50-2.00% manganese; 1.30-1.85% chromium; and 0.45-0.90% tungsten. 6. The steel of claim 1 , further comprising, by weight: 0.18-0.22% nitrogen; 0.18-0.22% carbon; 0.60-1.70% nickel; 0.50-2.00% manganese; 1.50-1.90% chromium; and 0.45-1.30% tungsten. 7. The steel of claim 1 , further comprising, by weight: 0.24-0.60% nitrogen; and 0.08-0.28% carbon; 0.10-1.00% nickel; 0.25-1.00% manganese; 1.20-2.70% chromium; and 0.45-1.50% tungsten. 8. The steel of claim 1 , wherein said steel at gas pressure of 40 bar (40 MPa) or greater, upon transition through casting solidification and cooling, comprises, partially by weight: up to 0.008% gas; and up to 28% delta ferrite. 9. A method of making a low alloy high nitrogen steel structure, the method comprising: providing a steel composition comprising iron and, by weight: 0.14-0.60% nitrogen (N), 0.08-0.28% carbon (C), 0.10-2.20% nickel (Ni), 0.25-2.00% manganese (Mn), 1.20-2.70% chromium (Cr), 0.45-1.50% tungsten (W), not more than 0.05% molybdenum (Mo), not more than 0.02% vanadium (V), not more than 0.60% silicon (Si), not more than 0.10% copper (Cu), not more than 0.02% titanium (Ti), not more than 0.02% niobium (Nb), not more than 0.008% aluminum (Al), and not more than 0.02% of any other element with not more than 0.10% total other elements, wherein cobalt (Co) is substitutable for any part of the nickel; casting liquid to solid, or solid state processing under a first atmosphere, then hot working or forming said steel composition to form to a shape; heating said steel composition to normalize or austenitize; quenching said steel composition at a rate to produce a substantially martensitic, bainitic, or mixed martensitic bainitic microstructure; and heating tempering said steel composition under a second gas atmosphere, wherein said second gas atmosphere comprises air, controlled atmosphere, or inert nitrogen or nitrogen and argon, or heating tempering in liquid environment. 10. The method of claim 9 , wherein the heating austenitizing further comprises heating and holding said steel composition to a temperature in a range of about 890° C. to about 950° C. 11. The method of claim 9 , wherein said quenching comprises at least one of: quenching into oil held at a temperature in a range of about 38° C. to about 177° C.; quenching into a solution of polymer and water held at a temperature in a range of about 27° C. to about 66° C.; quenching into a controlled stream of air or inert gas; applying a cryogenic treatment to a temperature in a range from about −78.5° C. to about −20° C.; and quenching into media at an intermediate temperature in a range from about 460° C. to about 550° C., holding for a predetermined time to harden said steel composition, followed by secondary quenching to a lower temperature. 12. The method of claim 9 , wherein said heating tempering comprises at least one of: a single tempering step; multiple tempering steps comprising at least one chilling between tempering steps; multiple tempering steps without chilling between tempering steps; a controlled rate of cooling following tempering to minimize, or eliminate, the possible occurrence of tempered martensite embrittlement; austempering, comprising intermediate quenching to a temperature in a range from about 440° C. to about 550° C. and holding prior to said quenching; and said quenching proceeding after a thermal mechanical treatment at a temperature in a range from about 860° C. to about 1000° C., wherein said tempering comprises at least one of a primary hardening at a temperature in a range from about 200° C. to about 440° C., or a at a temperature in a range from about 440° C. to about 650° C. 13. The method of claim 9 , further comprising hot working by rolling, forging or extrusion of said steel composition at a temperature in a range from about 1000° C. to about 1190° C. to a predetermined structure shape, said hot working comprising either increments or single steps of heating and reduction. 14. The method of claim 13 , further comprising performing heat treatments of a softening anneal process following said hot working, and following any softening anneal with a heat treatment comprising normalizing said steel composition at a temperature in a range from about 870° C. to about 1020° C. followed by air cooling. 15. The method of claim 14 , wherein after softening annealing, said method further comprising performing at least one of mechanical cutting, machining, flame cutting, plasma cutting, grinding, and sanding a finish dimension or surface of said low alloy high nitrogen steel structure. 16. The method of claim 13 , further comprising, prior to hot work, preheat and/or homogenizing said steel composition at a temperature in a heating range from about 870° C. to 1121° C. 17. The method of claim 9 , further comprising performing a solid state process of alloying, either by mechanical alloying of powder materials under N gas, N plus Ar gas, or N with ammonia or either first performing under N or with a controlled atmosphere of N with ammonia to perform diffusion of N gas into solid surfaces, powders, or thin sheet materials, wherein following mechanical alloying or a gas-solid diffusion N alloyed powder or thin sheets, are manufactured and consolidated to a final structure by any combinations of cleaning, surface finishing, cold isostatic pressing, hot isostatic pressing, sintering, hot work, austenitization, quench, or temper processing at or greater than atmospheric pressure. 18. The method of claim 17 , further comprising using hot isostatic pressure to obtain said final structure by packing and sealing a powder or thin sheets in a container under nitrogen gas, then performing any combination of (i) remotely pressurizing said container to provide specific N pressure and mass so as to equal the argon pressure level of the surrounding hot isostatic press and then heating said hot isostatic press to diffuse the mass of N to complete finished composition solid powd