Fig. 6.23 Bond zone pattern typical of explosion clad metals. Materials are type 304L stainless steel and medium-carbon steel. 20×. Source: Ref 6.1 More

Fig. 29 Radiograph of a pitted weld seam in a type 304L stainless steel tank bottom. Source: Ref 18 More

Fig. 30 Cross section through a pitted weld seam from a type 304L tank showing a typical subsurface cavity. Source: Ref 18 More

Fig. 38 Polarization curves for type 304L in the as-welded and pickled conditions. Source: Ref 21 More

Fig. 13.5 Cracks initiated on the outer diameter of the 304L clad tube, propagated inward to the substrate steel and terminated at the cladding-steel interface. Courtesy of Oak Ridge National Laboratory. More

Fig. 13.6 Cracks initiated on the outer surface of the 304L cladding, propagated inward to the substrate steel of the membrane and terminated at the cladding-steel interface. Courtesy of Oak Ridge National Laboratory. More

Fig. 31 Radiograph of a pitted weld seam in a type 304L stainless steel tank bottom. Source: Ref 10 More

Fig. 32 Cross section through a pitted weld seam from a type 304L tank showing a typical subsurface cavity. Source: Ref 10 More

Fig. 10.18 Corrosion rates of Types 304L and 310 as a function of H 2 S in the N 2 -5.1CO-16.7CO 2 -4.6H 2 O-0.55H 2 gas mixture at 370 °C (700 °F) for 1000 h. Source: Ref 28 More

Fig. 6.5 Flow stress vs. amount of deformation for 304L stainless steel at (a) cold and warm working temperatures and (b) hot working temperatures. Source: Ref 6.3 More

Fig. 9 Comparison of 304L chips with and without the Ugima oxide. Courtesy of Ugitech More

Fig. 7 Special finishes for 304/304L and 316/316L stainless steels available from one manufacturer. (a) Rolled-in low-glare finish (InvariMatte). (b) Rolled-in no. 4 finish (InvariBlend). (c) Rolled-in moderate-glare finish (InvariLux). Source: Contrarian Metal Resources ( Ref 8 ) More

Fig. 23.17 Ferrite in a plate of type 304L stainless steel. Light micrograph. Courtesy of S. Yun, Colorado School of Mines More

Fig. 5 Intergranular corrosion of a type 304L stainless steel tube in a shuttle orbiter ammonia boiler. (a) Test performed to show tube ductility. 1×. (b) Cross section through the thin-wall (0.2 mm, or 8 mils) tube revealing sensitization on outside diameter due to carbonaceous deposit formed More

Fig. 3.9 Effect of silicon and manganese on the oxygen content of 304L powders More

Fig. 5.20 Polished cross section of undersintered 304L revealing oxides in grain boundaries More

Fig. 7.5 Effect of temperature on the equilibrium nitrogen content of 304L in dissociated ammonia (D.A.) and nitrogen (bottom); and ultimate tensile strength (UTS) and elongation of 304L sintered in pure hydrogen at 1204 °C (2200 °F) and then nitrided in dissociated ammonia long enough More

Fig. 7.9 Fatigue curves for vacuum-sintered 304L and 316L as a function of sintered density. Sintered densities of 304L and 316L were 6.51 and 6.54 g/cm 3 , respectively. Sintered densities of 304L9 and 316L9 were 6.90 and 6.89 g/cm 3 , respectively. Sintering temperature was 1288 °C (2350 °F More

Fig. 11.16 SUS 304L stainless steel foam surface sintered at 1200 °C (2192 °F) Source: Ref 28 . Reprinted with permission from MPIF, Metal Powder Industries Federation, Princeton, NJ More

Fig. 11.17 Cross section of SUS 304L stainless steel foam. Source: Ref 28 . Reprinted with permission from MPIF, Metal Powder Industries Federation, Princeton, NJ More