Fig. 24-69 Warpage caused by nonuniform quenching of a 30% nickel steel block ( 10 ) More

Fig. 24-70 Effect of quenching on 30% nickel steel cylinder—water quenched from 1425 °F (774 °C) ( 10 ) More

Fig. 2.10 Effect of chromium and nickel on compressibility of chrome-nickel steels. Source: Ref 19 . Reprinted with permission from MPIF, Metal Powder Industries Federation, Princeton, NJ More

Fig. 5.44 Solubility of nitrogen in chromium-nickel steels in equilibrium with gaseous nitrogen or nitrides, depending on temperature and partial pressure of nitrogen. Source: Adapted from Ref 52 More

Fig. 7.18 Microstructure of a low-carbon steel sheet that was electroless nickel plated on both sides. (a) Specimen mounted in epoxy. (b) Specimen mounted in thermosetting phenolic resin. Note the damage in (b) due to the thermal-compression mounting process. Unetched. 100× More

Fig. 7.1 Microstructure of a nickel-plated AISI/SAE 1008 steel sheet specimen showing embedded silicon carbide particles from the grinding paper. The nickel layer pulled away from the mount during the curing process and produced a gap. The mount appears black, the nickel layer is unattacked More

Fig. 4.6 Effect of nickel content on SCC susceptibility of stainless steel wires containing 18 to 20% Cr in a magnesium chloride solution boiling at 154 °C (309 °F). After Ref 4.23 More

FIG. 5.2 The Pope bicycle used 5% nickel alloy steel for the frame. More

FIG. 5.3 The Haynes-Apperson Company used 5% nickel alloy steel for the first time in an automobile. Source: Brian Snelson. More

Fig. 2.8 Influence of nickel content on compressibility of 316L stainless steel powder. (Martensite formation is a significant contributor to the loss of compressibility in samples containing 8% and less nickel.) Source: Ref 17 More

Fig. 4.8 Coefficient of thermal expansion (CTE) of low-carbon steel and iron-nickel alloys as a function of temperature. The low CTE of iron-nickel alloys exists only over a limited range of temperature. Normal expansion behavior is observed above about 400 °C (750 °F). More

Fig. 16-1 Percent nickel in a series of heats of a cast Cr-Ni-Mo low-alloy steel ( 1 ) More

Fig. 24-30 End-quench hardenability of nickel (2320 and 2330) cast steel More

Fig. 24-31 End-quench hardenability of nickel-chromium (3130) cast steel More

Fig. 24-32 End-quench hardenability band for nickel-chromium (3140) cast steel More

Fig. 24-35 End-quench hardenability of nickel-chromium-molybdenum (4330) cast steel More

Fig. 6.18 Nickel distribution after peritectic reaction in a steel containing 4 wt% Ni. The temperature gradient was 60 K/cm. Calculations were made at different solidification rates. The dotted line shows the nickel distribution at the start of the peritectic reaction. δ, primary ferrite; γ More

Figure 11.35 Yield strength of high-nickel weld deposits in 9% Ni steel for two plate thicknesses, three welding positions, and two carbon contents ( Blake, Rowntree, and Phelps, 1973 ). More

Fig. 4.22 Test results of hydrogen embrittlement cracking of iron-nickel-cobalt steels. Source: Ref 4.31 More

Fig. 1 Effect of nickel additions to a 17 to 24% Cr steel on resistance to stress-corrosion cracking in boiling 42% magnesium chloride solution. Source: Ref 18 More