Fracture Behavior of Nickel-based Alloys in Water

The cracking resistance of Alloy 600, Alloy 690 and their welds, EN82H and EN52, was characterized by conducting JICtests in air and hydrogenated water. All test materials displayed excellent toughness in air and high temperature water, but Alloy 690 and the two welds were severeiy embrittled in low temperature water. In 54°C water with 150 cc Hz/kg H20, JICvalues were typically 70~o to !35Y0 ]Ower than their air counterparts. The toughness degradation was associated with a fracture mechanism transition from microvoid coalescence to intergmmdar fi-acture. Comparison of the cracking response in water with that for hydrogenprecharged specimens tested in air demonstrated that susceptibility to low temperature cracking is due to hydrogen embrittlement of grain boundaries. The effects of water temperature, hydrogen content and loading rate on low temperature crack propagation were studied. In addition, testing of specimens containing natural weld defects and as-machined notches was performed to determine if low temperature cracking can initiate at these features. Unlike the other materials, AUoy 600 is not susceptible to low temperature cracking as the toughness in 54°C water remained high and a microvoid coalescence mechanism was operative in both air and water.