Chromium-iron alloys -- DuctilitySee also what's at your library, or elsewhere.
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Filed under: Chromium-iron alloys -- Ductility
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Filed under: Chromium-iron alloys- The alloys of iron and chromium (Published for the Engineering foundation by McGraw-Hill, 1937), by Augustus Braun Kinzel, Russell Franks, Walter Crafts, and Engineering Foundation (U.S.) (page images at HathiTrust; US access only)
- Method for preparing ferrochromium alloys by vacuum reduction and simple melting of reduced products (U.S. Dept. of the Interior, Bureau of Mines, 1981), by S. E. Khalafalla, S. L. Payne, Michael L. Boucher, and J. E. Pahlman (page images at HathiTrust)
- Low-chromium heat-resisting ferritic alloys strengthened by the chi phase (U.S. Dept. of the Interior, Bureau of Mines, 1984), by M. L. Glenn and J. S. Dunning (page images at HathiTrust)
- Chromium recovery from high-temperature shift Cr-Fe catalysts (U.S. Dept. of the Interior, Bureau of Mines, 1988), by A. M. Stubbs and B. W. Jong (page images at HathiTrust)
- Structural stability and oxidation resistance of substitute alloys with various Cr and Mn levels (U.S. Dept. of the Interior, Bureau of Mines, 1989), by Je M. Oh and M. L. Glenn (page images at HathiTrust)
- Properties of arc-melted iron-chromium alloys (U.S. Dept. of the Interior, Bureau of Mines, 1962), by Gene Asai and H. Kato (page images at HathiTrust)
- Low-temperature chlorination of ferrochromium : preliminary studies (U.S. Dept. of the Interior, Bureau of Mines, 1968), by Robert L. De Beauchamp and Thomas A. Sullivan (page images at HathiTrust)
- High-carbon ferrochromium report to the president on investigation no. TA-201-35 under section 201 of the Trade Act of 1974. (U.S. International Trade Commission, 1978), by Lynn Featherstone and United States International Trade Commission (page images at HathiTrust)
- High carbon ferrochromium : report to the President on investigation no. TA-201-28 under section 201 of the Trade act of 1974. (U.S. International Trade Commission, 1977), by United States International Trade Commission, Mary Youdin, N. Timothy Yaworski, and Lynn Featherstone (page images at HathiTrust)
- Low-carbon ferrochromium : report to the President on investigation no. TA-201-20 under section 201 of the Trade act of 1974 (The Commission, 1977), by United States International Trade Commission, Marvin Claywell, James S. Kennedy, and Nicholas C. Tolerico (page images at HathiTrust)
- Erosion of iron-chromium alloys by glass particles (National Aeronautics and Space Administration, Scientific and Technical Information Branch ;, 1984), by Joshua Salik, Donald H. Buckley, and United States. National Aeronautics and Space Administration. Scientific and Technical Information Branch (page images at HathiTrust)
- Friction and wear characteristics of iron-chromium alloys in contact with themselves and silicon carbide (National Aeronautics and Space Administration, Scientific and Technical Information Office ;, 1979), by Kazuhisa Miyoshi, Donald H. Buckley, and United States. National Aeronautics and Space Administration. Scientific and Technical Information Office (page images at HathiTrust)
- The effect of impurities on iron-chromium-yttrium alloys (Battelle Memorial Institute ;, 1959), by Ronald F. Dickerson, Ellis L. Foster, Walston Chubb, Roy W. Endebrock, U.S. Atomic Energy Commission, and Battelle Memorial Institute (page images at HathiTrust)
- Solubility limits of yttrium and the lanthanide rare-earth elements in chromium and chromium-iron alloys (Battelle Memorial Institute ;, 1959), by Seymour G. Epstein, Ronald F. Dickerson, Arthur A. Bauer, U.S. Atomic Energy Commission, and Battelle Memorial Institute (page images at HathiTrust)
- Report on the chrome iron ore deposits in the Eastern Townships, province of Quebec (Govt. Print. Bureau, 1909), by Fritz Cirkel and Canada. Mines Branch (page images at HathiTrust; US access only)
- Resistance to attack by sodium (Knolls Atomic Power Laboratory ;, 1954), by E. G. Brush, R. F. Koenig, Knolls Atomic Power Laboratory, General Electric Company, and U.S. Atomic Energy Commission (page images at HathiTrust)
Filed under: Chromium-iron alloys -- CorrosionFiled under: Chromium-iron alloys -- Oxidation
Filed under: Chromium-iron alloys -- Taxation -- United StatesFiled under: Ferrochrome- Method for preparing ferrochromium alloys by vacuum reduction and simple melting of reduced products (U.S. Dept. of the Interior, Bureau of Mines, 1981), by S. E. Khalafalla, S. L. Payne, Michael L. Boucher, and J. E. Pahlman (page images at HathiTrust)
- Equilibria in the reduction of chromic oxide by carbon, and their relation to the decarburization of chromium and ferrochrome (U.S. Dept. of the Interior, Bureau of Mines, 1944), by F. S. Boericke (page images at HathiTrust)
- Application of cast-on ferrochrome-based hard surfacings to polystyrene pattern castings (U.S. Dept. of the Interior, Bureau of Mines, 1985), by G. F. Soltau, S. J. Gerdemann, R. R. Jordan, and J. S. Hansen (page images at HathiTrust)
- Beneficiation of ferrochromium by molten salt electrolysis (U.S. Dept. of the Interior, Bureau of Mines, 1969), by Francis R. Cattoir, Thomas A. Sullivan, and United States Bureau of Mines (page images at HathiTrust)
- Ferrochromium from western metallurgical-grade chromite (U.S. Dept. of the Interior, Bureau of Mines, 1961), by W. L. Hunter and Gary A. Kingston (page images at HathiTrust)
- Pyrometallurgical beneficiation of offgrade chromite and production of ferrochromium (U.S. Dept. of the Interior, Bureau of Mines, 1962), by W. L. Hunter and Lloyd Harold Banning (page images at HathiTrust)
- Decarburization of ferrochromium by hydrogen (U.S. Dept. of Commerce, Bureau of Standards :, 1922), by Louis Jordan, Frank Evans Swindells, and United States. National Bureau of Standards (page images at HathiTrust)
Filed under: Tariff on chromium-iron alloys -- United States
Filed under: Chromium alloys -- Ductility- Ductility mechanisms and superplasticity in chromium alloys (National Aeronautics and Space Administration ;, 1968), by Joseph R. Stephens, William D. Klopp, and Lewis Research Center (page images at HathiTrust)
- Review of ductilizing of Group VIA elements by rhenium and other solutes (National Aeronautics and Space Administration ;, 1968), by William D. Klopp, United States National Aeronautics and Space Administration, and Lewis Research Center (page images at HathiTrust)
- Properties of dispersion-strengthened chromium-4-volume-percent-thoria alloys produced by ball milling in hydrogen iodide (National Aeronautics and Space Administration ;, 1974), by Alan Arias and Lewis Research Center (page images at HathiTrust)
Filed under: Chrome-nickel steel -- DuctilityFiled under: Chromium-iron-nickel alloys -- Ductility
Filed under: Ductility- An investigation of hot ductility of inconel and inconel x (Oak Ridge National Laboratory, 1958), by Edward A. Pigan and U.S. Atomic Energy Commission (page images at HathiTrust)
- Influence of several metallurgical variables on the tensile properties of hastelloy N (Oak Ridge National Laboratory, 1964), by H. E. McCoy and U.S. Atomic Energy Commission (page images at HathiTrust)
- Instrumental impact and residual tensile strength testing of eight-ply carbon/epoxy specimens (National Aeronautics and Space Administration, Office of Management, Scientific and Technical Information Division ;, 1990), by A. T. Nettles and George C. Marshall Space Flight Center (page images at HathiTrust)
- Comparison of polyester, film-yarn composite, balloon materials subjected to shear and biaxial loading (National Aeronautics and Space Administration ;, 1972), by R. J. Niccum, Langley Research Center, and G.T. Schjeldahl Company (page images at HathiTrust)
- Refractory metal valves for 1900 deg F service in alkali metal systems (National Aeronautics and Space Administration ;, 1971), by R. W. Harrison, J. Holowach, Lewis Research Center, and General Electric Company (page images at HathiTrust)
- Thermal fatigue of ductile materials. III, Behavior of crucible 422 steel (National Aeronautics and Space Administration, 1959), by Francis J. Clauss and Lewis Research Center (page images at HathiTrust)
- Ductile ceramics. I, Factors affecting the plasticity of sodium chloride, lithium fluoride, and magnesium oxide single crystals (National Aeronautics and Space Administration, 1959), by Carl A. Stearns, Robert A. Lad, Ann E. Pack, and Lewis Research Center (page images at HathiTrust)
- Ductile ceramics. II, Introductory study of ductility in polycrystalline sodium chloride and magnesium oxide (National Aeronautics and Space Administration, 1959), by Charles E. May, Robert A. Lad, Hubert H. Grimes, and Lewis Research Center (page images at HathiTrust)
- Aerodynamic characteristics of a powered semispan tilting-shrouded-propeller VTOL model in hovering and transition flight (National Aeronautics and Space Administration, 1962), by Kenneth W. Goodson, Kalman J. Grunwald, United States National Aeronautics and Space Administration, and Langley Research Center (page images at HathiTrust)
- Vacuum-induction, vacuum-arc, and air-induction melting of a complex heat-resistant alloy (National Aeronautics and Space Administration, 1959), by Raymond Frank Decker, J. W. Freeman, John P. Rowe, and University of Michigan (page images at HathiTrust)
- On the ductile enlargement of voids in triaxial stress fields (Division of Engineering, Brown University, 1968), by J. R. Rice, D. M. Tracey, U.S. Atomic Energy Commission, and Brown University. Division of Engineering (page images at HathiTrust)
- Strain-hardening and interaction effects on the growth of voids in ductile fracture (Division of Engineering, Brown University, 1968), by D. M. Tracey, U.S. Atomic Energy Commission, and Brown University. Division of Engineering (page images at HathiTrust)
- Significant issues in proof testing : a critical appraisal (National Aeronautics and Space Administration, George C. Marshall Space Flight Center, 1994), by G. G. Chell and George C. Marshall Space Flight Center (page images at HathiTrust)
Filed under: Ductility -- Mathematical models
Filed under: Alloys -- Ductility- Research on chromium-base alloys exhibiting high-temperature strength, low-temperature ductility, and oxidation resistance (Wright-Patterson Air Force Base, Ohio : Directorate of Materials and Processes, Aeronautical Systems Division, Air Force Systems Command, United States Air Force, 1963., 1963), by Carl S. Wukusick, United States. Air Force. Systems Command. Aeronautical Systems Division, and General Electric Company. Nuclear Materials and Propulsion Operation (page images at HathiTrust)
Filed under: Aluminum alloys -- Ductility- Effect of service usage on tensile, fatigue, and fracture properties of 7075-T6 and 7178-T6 aluminum alloys (National Aeronautics and Space Administration ;, 1975), by Richard A. Everett and Langley Research Center (page images at HathiTrust)
- Tensile properties and creep strength of three aluminum alloys exposed up to 25,000 hours at 200 ̊to 400 ̊F (370 ̊to 480 ̊K) (National Aeronautics and Space Administration ;, 1969), by Dick M. Royster, United States National Aeronautics and Space Administration, and Langley Research Center (page images at HathiTrust)
- Flaw growth behavior in thick welded plates of 2219-T87 aluminum at room and cryogenic temperatures (National Aeronautics and Space Administration ;, 1973), by Royce G. Forman, James D. Medlock, Samuel V. Glorioso, United States National Aeronautics and Space Administration, and Lyndon B. Johnson Space Center (page images at HathiTrust)
- Factors affecting the ductility of iron-chromium-aluminum alloy sheet (Battelle Memorial Institute ;, 1960), by Roy W. Endebrock, Ronald F. Dickerson, Ellis L. Foster, U.S. Atomic Energy Commission, and Battelle Memorial Institute (page images at HathiTrust)
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