On the factors influencing the elastoplastic cyclic response and low cycle fatigue failure of AISI 316L steel produced by laser-powder bed fusion

“…LCF results and experimental dataset are the same as those reported in an authors' previous work, 31 which constitutes a companion study of the present article. For the sake of clarity, the main aspects related to the analyzed material are briefly summarized in the following.…”

“…Examples of stress-strain cycles recorded at strain amplitudes 0.3%, 0.6%, and 1.2% are depicted in Figure 1A. It is worth reminding from the authors' previous work 31 that, for each strain amplitude tested, the L-PBF AISI 316L steel exhibits a very brief hardening behavior followed by a continuous cyclic softening until final failure, as shown in Figure 1B. As no material stabilized state is clearly visible, the stress-strain cycles at half-life are conventionally assumed to represent the stabilized state.…”

“…For the sake of clarity, the main aspects related to the analyzed material are briefly summarized in the following. Cylindrical rods of AISI 316L stainless steel were vertically produced by L‐PBF (Concept Laser M2 Cusing machine) using the process parameters fully given in Pelegatti et al 31 The “island” scanning strategy was adopted to melt the powder in each layer, with a 90° rotation and 1 mm shift between successive layers. Before the removal from the building platform, a stress relief treatment at a temperature of 550°C for 6 h was performed on the rods.…”

“…In the authors' previous study, 31 the experimental strain amplitude‐life data were used to estimate the Manson–Coffin model 48 : where and are the elastic and plastic strain amplitudes. In Equation (13), the elastic part is ruled by the fatigue strength coefficient and exponent and the plastic part by the fatigue ductility coefficient and exponent .…”

“…In the authors' previous study, 31 the experimental strain amplitude-life data were used to estimate the Manson-Coffin model 48 :…”

Strain‐controlled fatigue loading of an additively manufactured AISI 316L steel: Cyclic plasticity model and strain–life curve with a comparison to the wrought material

“…LCF results and experimental dataset are the same as those reported in an authors' previous work, 31 which constitutes a companion study of the present article. For the sake of clarity, the main aspects related to the analyzed material are briefly summarized in the following.…”

“…Examples of stress-strain cycles recorded at strain amplitudes 0.3%, 0.6%, and 1.2% are depicted in Figure 1A. It is worth reminding from the authors' previous work 31 that, for each strain amplitude tested, the L-PBF AISI 316L steel exhibits a very brief hardening behavior followed by a continuous cyclic softening until final failure, as shown in Figure 1B. As no material stabilized state is clearly visible, the stress-strain cycles at half-life are conventionally assumed to represent the stabilized state.…”

“…For the sake of clarity, the main aspects related to the analyzed material are briefly summarized in the following. Cylindrical rods of AISI 316L stainless steel were vertically produced by L‐PBF (Concept Laser M2 Cusing machine) using the process parameters fully given in Pelegatti et al 31 The “island” scanning strategy was adopted to melt the powder in each layer, with a 90° rotation and 1 mm shift between successive layers. Before the removal from the building platform, a stress relief treatment at a temperature of 550°C for 6 h was performed on the rods.…”

“…In the authors' previous study, 31 the experimental strain amplitude‐life data were used to estimate the Manson–Coffin model 48 : where and are the elastic and plastic strain amplitudes. In Equation (13), the elastic part is ruled by the fatigue strength coefficient and exponent and the plastic part by the fatigue ductility coefficient and exponent .…”

“…In the authors' previous study, 31 the experimental strain amplitude-life data were used to estimate the Manson-Coffin model 48 :…”

Strain‐controlled fatigue loading of an additively manufactured AISI 316L steel: Cyclic plasticity model and strain–life curve with a comparison to the wrought material

Additive manufacturing of heat exchangers in aerospace applications: a review

Fatigue behavior of selective laser melted 316L stainless steel: Experiments and modeling