転位の水素トラップ占有率に基づく高圧水素ガス中における水素拡散特性と各種破壊特性の統一的解釈―オーステナイト系ステンレス鋼と低合金鋼

抄録

A binding energy, E_B, and the number of trap sites, N_X, of hydrogen trapped in cold-rolled austenitic stainless and quenched-tempered low alloy steels exposed in high-pressure hydrogen gas were determined from a linear relationship between the concentration of the trapped hydrogen, N_HX, and the trap-site occupancy, θ_X, which is a function of E_B and N_X, being calculated from the Oriani’s local equilibrium theory. The determinations identified that E_B = 28 kJ/mol and N_X = 2.12×10²⁵ /m³ for 30% cold-rolled SUS316L (heat of B); E_B = 28 kJ/mol and N_X = 3.83×10²⁵ /m³ for 60% cold-rolled SUS316L (heat of B); E_B = 24 kJ/mol and N_X = 2.29×10²⁵ /m³ for 30% cold-rolled SUS304 (heat of B); E_B = 43 kJ/mol and N_X = 2.68×10²⁴ /m³ for SCM435 (heat JL); E_B = 42 kJ/mol and N_X = 2.80×10²⁴ /m³ for SCM435 (heat KL); E_B = 42 kJ/mol and N_X = 2.20×10²⁴ /m³ for SNCM439 (heat BL); E_B = 42 kJ/mol and N_X = 2.42×10²⁴ /m³ for SNCM439 (heat GL). From binding energies reported in existing literatures and the size of dislocation cores, the trapped hydrogen in cold-rolled austenitic stainless and quenched-tempered low alloy steels was mainly trapped by dislocation cores. For the low alloy steels, furthermore, hydrogen-induced degradations (HIDs) of various fracture characteristics were linearly proportional to θ_X and the following values of E_B were obtained: E_B = 44 kJ/mol for fatigue crack growth characteristics in hydrogen gas at pressures, p, of 0.1 ~ 95 MPa and temperatures, T, of 25 ~ 95℃ for SCM435 (heat TS); E_B = 44 kJ/mol for fracture toughness characteristics in hydrogen gas at p = 0.7 ~ 115 MPa and T = 25℃ for SCM435 (heat of KL); E_B = 43 ~ 46 kJ/mol for slow strain rate tensile characteristics in hydrogen gas at p = 115 MPa and T = −45 ~ 120℃ for SCM435 (heats JL and KL) and SNCM439 (heats BL and GL). The values of E_B obtained from the strength characteristics were nearly equal to those from the hydrogen-diffusion. A series of analyses implied that the hydrogen-diffusion characteristics and the HIDs of various facture characteristics were dominated by the interaction of hydrogen and dislocation cores; then, the characteristics under various combinations of p and T could be predicted by the unified parameter, θ_X.