Cyclic Strength and Nonlinear Material Fracture Mechanics (by the example of steels)

Abstract

It was shown that a material fatigue fracture diagram can be viewed as a locus of points with σ and l coordinates' product equal to K1c/2, and σ and l product -- to G1c/2, where K1c and G1c are non-linear fracture mechanics force and energy criteria. It was established that the average number of interatomic bonds destroyed within one alternate stress ∇1cs cycle is directly proportional to σ that is twice as large as a peak value of σa. It was found that low-cycle fatigue is characterized by σ >σ0.2 and σ1cs> 1, high-cycle fatigue -- by σ = σ0.2 and ∇1cs = 1, and giga-cycle fatigue -- by σ < σ0.2 and ∇1cs < 1. An individual interatomic bond cannot be destroyed part by part but as a single unit. The latter means that in giga-cycle fatigue a single interatomic bond is destroyed within several cycles rather than within a single cycle. The factors F (collapsibility) and R (resistibility) were proposed and mentioned as essential material physical constants. The introduced notion ∇1cs and the established linear nature of ∇1cs relationship allow to: a) clarify the fatigue crack growth physical nature in low-, high- and giga-cycle fracture zones; b) determine the nature of a fatigue fracture diagram disruption; c) plot the fatigue fracture diagram using the results obtained in a single specimen cyclic strength test with a selected value of σ σ0.2. For giga-cycle fatigue it is important (with similar purpose in mind) to determine this dependence for σ < σ0.2. It is recommended to use G1c criterion to find the lcr length value which in contrast to K1c has a clear physical nature.