Search Results for diameter

Fig. 4 Relationship of the critical diameter, D , to the ideal critical diameter, D I , for several rates of cooling, H . Adapted from Ref 4 More

Fig. 1 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. 24 Upsetting (a) of bar diameter d to head diameter D . (b) Material fracture strain limits are superimposed on strain paths reaching the final required strain. Strain path b (low friction) prevents fracture for both materials. Material B avoids fracture for either strain path. More

Fig. 5 Pin diameter as a function of shoulder diameter, from the literature More

Fig. 38 Typical fiber sizes. MFD, mode field diameter; CLD, cladding diameter; NA, numerical aperture More

Fig. 46 Ideal critical diameter ( D I ) versus actual diameter ( D ) for various quench severity ( H ) factors More

Fig. 16 Electric-arc-sprayed steel coating using smaller-diameter wires. Courtesy of Praxair TAFA (formerly Miller Thermal) More

Fig. 3 Cylindrical or outer-diameter grinder used on outer diameters of cylinders between centers More

Fig. 5 Internal or inner-diameter grinder for grinding the inner diameters of cylinders with a small wheel on a shaft at high revolutions per minute More

Fig. 7 Honing shaft for inner-diameter finishing More

Fig. 2 Effect of temperature on mass change of 23 mm (1 in.) diameter by 3 mm (0.12 in.) thick iron samples located on the iron cathode and plasma nitrided in a mixture of 25% nitrogen and 75% hydrogen at two different pressures. Adapted from Ref 6 More

Fig. 9 Use of equivalent diameter to relate (a) internal and (b) external cylindrical grinding to surface grinding More

Fig. 2 Relationship between Jominy distance and ideal critical diameter, D I . Source: Ref 3 More

Fig. 7 Ideal critical diameter ( D I ) relationship between 1, 10, and 50% structure criteria. P, pearlite; B, bainite. Source: Ref 5 More

Fig. 11 Relationship between through-quenched round bar diameter and through-quenched thickness of plates and square bars. Source: Ref 11 More

Fig. 12 Charts for the interconversion of critical diameter and ideal critical diameter if the Grossmann hardenability ( H ) value is known. (a) For small bars. (b) For large bars. Source: Ref 45 More

Fig. 13 Grossmann's interrelationship between quench severity ( HD ), bar diameter ( D ), and depth of hardening ( D U / D ). Source: Ref 53 More

Fig. 16 Two-diameter test bar recommended by Rushman. Source: Ref 71 More

Fig. 26 A 13 mm (0.5 in.) diameter type 304 cylindrical stainless steel probe with a conical end. The dimensions for length ( L ) = 57 mm (2.3 in.) and height ( h ) = 10 mm (0.4 in.), reported by Hernández-Morales and López-Valdéz. One thermocouple is inserted to a depth of 40 mm (1.6 More

Fig. 61 Cooling curves obtained using a 5 mm (0.2 in.) diameter by 10 mm (0.4 in.) AISI 321 stainless steel wire probe with a center thermocouple in molten lead at three bath temperatures. Source: Ref 161 More