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steel sheets

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Published: 01 August 2013
Fig. 5.6 Temperature changes during continuous annealing of DP steel sheets. Source: Ref 5.3 More
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Published: 31 October 2024
Fig. 5.6 Temperature changes during continuous annealing of dual-phase steel sheets. M s , martensite start temperature. Source: Ref 5.3 More
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Published: 01 August 2018
Fig. 12.11 Low carbon steel sheet C = 0.06%, Mn = 0.55%, after cold working, in the work hardened state, prior to annealing. Very elongated grains of ferrite and cementite. Hardness: 95 HRB. More
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Published: 01 August 2012
Fig. 6.4 Engineering stress-strain curves of five advanced high-strength steel sheet materials. Source: Ref 6.7 More
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Published: 01 November 2013
Fig. 23 Laminations in rolled steel sheet resulting from insufficient cropping of the pipe from the top of a conventionally cast ingot. Courtesy of V. Demski, Teledyne Rodney Metals. Source: Ref 14 More
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Published: 01 November 2013
Fig. 24 Forming limit diagram for aluminum-killed steel sheet. Adapted from Ref 14 More
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Published: 01 November 2012
Fig. 6 Corrosion pits in thin-walled austenitic stainless steel sheet approximately 0.5 mm (0.02 in.). Courtesy of M.D. Chaudhari. Source: Ref 5 More
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Published: 01 December 2001
Fig. 4 Deep-drawing properties of steel sheet grades More
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Published: 01 August 2018
Fig. 13.31 Cross section of steel sheet galvanized by immersion. No etching. More
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Published: 01 August 2018
Fig. 13.33 Cross section of a steel sheet coated by galvalume. No etching. More
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Published: 01 March 2002
Fig. 5.47 Micrographs of a cold-worked AISI 316 stainless steel sheet taken with (a) bright-field illumination and (b) differential interference contrast illumination. Note the excellent clarity of surface relief in the differential interference contrast illumination. Electrolytic etch (10 More
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Published: 01 March 2002
Fig. 7.1 Microstructure of a nickel-plated AISI/SAE 1008 steel sheet specimen showing embedded silicon carbide particles from the grinding paper. The nickel layer pulled away from the mount during the curing process and produced a gap. The mount appears black, the nickel layer is unattacked More
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Published: 01 March 2002
Fig. 7.12 Microstructure of a dual-phase steel sheet showing the results of deformation by shearing. (a) Correct dual-phase microstructure away from the shear burr. (b) Shear burr region where pools of retained austenite have transformed to martensite by the plastic deformation. Arrows More
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Published: 01 March 2002
Fig. 7.18 Microstructure of a low-carbon steel sheet that was electroless nickel plated on both sides. (a) Specimen mounted in epoxy. (b) Specimen mounted in thermosetting phenolic resin. Note the damage in (b) due to the thermal-compression mounting process. Unetched. 100× More
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Published: 01 March 2002
Fig. 7.21 Micrographs showing low-carbon steel sheet with the tight interface that can be achieved in a mechanical clamp (clamp shown above specimen) (a) and the flat edges of two sheet specimens in a mechanical clamp with a gap between specimens (b). Marshall’s etch. 500× More
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Published: 01 March 2002
Fig. 7.27 Steel sheet placed next to the specimen in an epoxy mount for edge retention More
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Published: 01 March 2002
Fig. 8.39 Very-low-carbon motor lamination steel sheet showing columnar grains growing from the sheet surface and equiaxed ferrite grains in the center. Beraha’s reagent. 75× More
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Published: 01 January 2015
Fig. 12.29 Engineering stress-strain curves for 10B22 steel sheet specimens water quenched to martensite and tempered at the temperatures shown for 1 hour. Source: Ref 12.75 More
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Published: 01 March 2002
Fig. 3.11 Microstructure of a cold-rolled, low-carbon steel sheet. Cold-worked (a) 30%, (b) 50%, (c) 70%, and (d) 90%. Marshall’s etch. 500× More
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Published: 01 March 2002
Fig. 3.16 Microstructure of cold-rolled, interstitial-free steel sheet that has been annealed for 1 min at (a) 649 °C (1200 °F), (b) 676 °C (1250 °F), (c) 704 °C (1300 °F), and (d) 732 °C (1350 °F). Marshall’s etch. 400× More