Fig. 17 AISI Type 410: Effect of tempering temperature on impact properties. Impact energy tests used Izod, Charpy V-notch, or Charpy keyhole as indicated. Heat treatment of test specimens: heated to and held at 955 °C (1750 °F) for 1 h; oil quenched, tempered for 4 h at temperature given; air More

Fig. 1 Effect of the crystallinity of an impact modifier on impact properties. PE, polyethylene; PP, polypropylene; HDPE, high-density polyethylene. Source: Ref 9 More

Fig. 27 Effect of drawing temperature on the impact properties of hot-drawn bars of two steels. Source: Ref 12 More

Fig. 3 Tensile and impact properties of fully quenched and tempered boron steels superimposed on normal expectancy bands for medium-carbon low-alloy steels without boron More

Fig. 19 Effect of hot mill finishing temperature on impact properties of 1541 steel containing 0.10% V. Source: Ref 23 More

Fig. 17 Effect of heat treatment on Charpy V-notch impact properties of ductile iron. Source: Ref 9 Sample (a) Heat treatment A As-cast B Subcritical annealed C Quenched and tempered J Quenched and tempered G Quenched and tempered E Normalized and tempered More

Fig. 25 Effect of heat treatment on Charpy V-notch impact properties of ductile iron. Souce: Ref 40 More

Fig. 26 Influence of density on the tensile and impact properties of PF-4600 materials with core hardnesses of 25 to 30 HRC and 28 to 31 HRC. (a) Ultimate tensile strength. (b) Percent reduction of area. (c) Percent elongation. (d) Room-temperature impact energy. Closed circle datapoints: Ref More

Fig. 27 Influence of density on the tensile and impact properties of PF-4600 materials with core hardnesses of 38 to 42 HRC and 45 to 50 HRC. (a) Ultimate tensile strength. (b) Percent reduction of area. (c) Percent elongation. (d) Room-temperature impact energy. Closed circle datapoints: Ref More

Fig. 15 Effect of rare-earth additions on impact properties of Al-Si killed X65 pipeline steel. More

Fig. 17 Effect of heat treatment on Charpy V-notch impact properties of ductile iron. Source: Metals Handbook , 9th ed., Vol 1, p 42 More

Fig. 23 Effect of carbon content on impact properties. Source: Ref 4 as published in Ref 3 More

Fig. 18 Charpy C-notch impact properties of CPM 9V and other P/M and conventional tool steels at indicated hardnesses for cold-work applications More

Fig. 21 Charpy C-notch impact properties of CPM 10V and other P/M and conventional tool steels at indicated hardnesses More

Fig. 23 Effect of tempering temperature and density on impact properties of FL-4205. Source: Ref 22 More

Fig. 18 Effect of hot forging on impact properties of an alloy steel. With increasing hot working, the properties in the elongation direction improve by a factor of four (longitudinal curve), while in the transverse direction (perpendicular to the fiber direction), they improve by a factor More

Fig. 27 Influence of density on the tensile and impact properties of P/F-4600 materials with core hardnesses of 25 to 30 HRC and 28 to 31 HRC. (a) Ultimate tensile strength. (b) Percent reduction of area. (c) Percent elongation. (d) Room-temperature impact energy. See also Fig. 28 More

Fig. 28 Influence of density on the tensile and impact properties of P/F-4600 materials with core hardnesses of 38 to 42 HRC and 45 to 50 HRC. (a) Ultimate tensile strength. (b) Percent reduction of area. (c) Percent elongation. (d) Room-temperature impact energy. See also Fig. 27 More

Fig. 14 Charpy C-notch impact properties of P/M and conventional tool steels at indicated hardness for cold-work applications More

Fig. 29 Effect of heat treatment on Charpy V-notch impact properties of ductile iron. Source: Ref 43 More