Search Results for diameter

Fig. 6 Sintered bush. (a) Outside diameter wear. (b) Outside diameter crack More

Fig. 9 Quench of a 25 mm diameter × 100 mm (1.0 in. diameter × 4 in.) cylinder of a CrNi steel into water at 30 °C (85 °F) with an agitation rate of 0.3 m/s (1 ft/s). Courtesy of H.M. Tensi, Technical University of Munich More

Fig. 2.9 Critical diameter as a function of diameter for round bars. Source: Ref 2 More

Fig. 4.50 Outside-diameter heat, inside-diameter quench. Source Ref 12 More

Fig. 12.17 Influence of specimen diameter/mean grain diameter ratio and solution temperature on the creep-rupture properties of a wrought nickel-base superalloy tested at 870 °C (1600 °F)/138 MPa (20 ksi). Note: Grain size was a function of solution temperature, as shown on MCR plot. More

Fig. 7.7 Influence of the ratio tool set diameter, d , to the diameter of the pressure ring in the press front platen, D , on bending as a function of the increasing pressure ring radius. Source: SMS-Emoco More

Fig. 11.15 Plot of base diameter, D B , used for calculating ideal diameter. Source: Ref 2 More

Fig. 11.16 Relationship between ideal diameter and critical diameter. Source: Ref 8 More

Fig. 3 Circumscribing circle diameter (CCD). OD, outside diameter More

Fig. 3-16 The ratio of the unhardened diameter D u to that of the diameter D versus the diameter D, from the photographs in Fig. 3-15 . Note that at D u /D = 0, the diameter is the critical diameter D 0 = 1.05 inch for the quench used More

Fig. 4-19 Hardness across the diameter of 1 and 3 inch diameter cylinders when using quenchants of H = 0.20, 1.00 and ∞. These curves are based on the minimum in the hardenability band of a 1340H steel More

Fig. 4-20 Hardness across the diameter of 1 and 3 inch diameter cylinders when using quenchants of H = 0.20, 1.00 and ∞. These curves are based on the minimum in the hardenability band of a 4340H steel More

Fig. 4.5 Flat layout of a multihole die. ID, inside diameter; OD, outside diameter More

Fig. 5.17 Critical diameter as a function of diameter for round bars. Source: Ref 2 More

Fig. 5 High-temperature sulfidic corrosion of 150 mm (6 in.) diameter carbon steel tube from radiant section of crude preheat furnace at crude distillation unit. Note accelerated attack on fire side. More

Fig. 45 Accelerated high-temperature sulfidic corrosion in 500 mm (20 in.) diameter pipe of vacuum furnace outlet header due to droplet impingement at high vapor velocities More

Fig. 22 Cracked shaft used in a corrosive environment. Diameter of the shaft is approximately 10 cm (4 in.). More

Fig. 5 (a) Crankshaft flanges not filled. Main shaft diameter shown between flanges of adjacent “throws”. (b) Crankshaft flange with left side filled and right side not filled. Pinion shaft diameter located between flanges of single “throw” More

Fig. 6 Both crankshaft flanges filled. Pinion shaft diameter located between flanges of single “throw” More