Search Results for Elongation

Fig. 14 Effect of gage length on the percent elongation. (a) Elongation, %, as a function of gage length for a fractured tension test piece. (b) Distribution of elongation along a fractured tension test piece. Original spacing between gage marks, 12.5 mm (0.5 in.). Source: Ref 7 More

Fig. 3 (a) Force-elongation and (b) modulus-elongation curves for twisted (Z60 = 60 tpm, blue) and untwisted (red) Twaron 1000, 3360 dtex yarns. Courtesy of Teijin Aramid More

Fig. 3 Variation in elongation, tensile strength, and hardness with temperature. Watts bath operated at 54 °C and 5 A/dm 2 . Source: Ref 1 More

Fig. 4 Variation in internal stress, elongation, tensile strength, and hardness with chloride content in deposits from Watts solutions operated at 55 °C, pH 3.0, and 5 A/dm 2 . Internal stress is tensile (indicated by a positive number). Source: Ref 1 More

Fig. 5 Hardness and elongation of Ni-10Co and Ni-15Co alloys after heating to various temperatures More

Fig. 2 Relation between tensile strength and total elongation for various HSLA sheet steels. Source: Ref 3 More

Fig. 17 Variation in total elongation and tensile strength of 0.2 to 0.4% C steels containing 1.2% Si and 1.2% Mn. Numbers in symbols indicate the percentage of retained austenite, γ R . Source: Ref 17 More

Fig. 50 Effect of test temperature on ductility. (a) Elongation in 50 mm (2 in.) and (b) reduction in area for annealed specimens of 2 1 4 Cr-1Mo steel tested at the indicated temperatures. Source: Ref 84 More

Fig. 30 Influence of bar diameter on the tensile strength (a) and elongation (b) of blackheart malleable iron. Source: Ref 30 More

Fig. 2 Proposed strength and elongation ranges of austempered ductile iron compared to established criteria for other grades of ductile iron. DIS, Ductile Iron Society; BCIRA, British Cast Iron Research Association More

Fig. 3 Tensile strength and elongation relationship for various ductile iron grades. Source: Ref 1 More

Fig. 6 Correlation between hardness, tensile strength, and elongation in CG irons. Source: Ref 8 More

Fig. 7 Correlation between yield strength and elongation for CG and SG irons. Source: Ref 8 More

Fig. 11 Correlation between nodularity and elongation for ferritic CG iron. Source: Ref 16 More

Fig. 6 Variation in average percent elongation as a function of oxide count (LAIS). Source: Ref 2 More

Fig. 14 Effect of increasing hydrogen content of melt on percent elongation of A356 aluminum alloy. Source: Ref 2 More

Fig. 15 Effect of increasing hydrogen content of melt on percent elongation of a 319 aluminum alloy. Source: Ref 2 More

Fig. 7 Elongation of Thixoblends as a function of blend composition and α prim solid fraction More

Fig. 9 Correlation among hardness, tensile strength, and elongation in compacted graphite irons. Source: Ref 17 More

Fig. 15 Correlation between nodularity and elongation for ferritic compacted graphite. Source: Ref 24 More