Inelastic Response and Stability of Titanium Alloy Tubes under Cyclic Bending.

“…As the cyclic process continues, the ovalization keeps accumulating. A similar test result was also reported by Kyriakides and Shaw (2) for 606l-T6 aluminum and l018 steel tubes and Hsu et al (9) for titanium alloy tubes. Figure 8 shows a picture of the local buckling of the 316L stainless steel tubes under cyclic bending.…”

“…The intrinsic time measure ζ is dζ = de p ∼ (9) in which · represents the Euclidean norm. The material function (or hardening function) f (ζ) is…”

“…The tubes used by them were the same as that used by Pan et al (1) Pan and Her (8) investigated the response and stability of SUS 304 stainless steel tubes subjected to cyclic bending with different curvature-rates. Hsu et al (9) investigated the elastoplastic response and stability of titanium alloy tubes subjected cyclic bending and Lee and Pan (10) investigated the viscoplastic response and stability of titanium alloy tubes subjected cyclic bending. Lee et al (11) discussed the influence of the diameter-tothickness ratio to the response and stability of SUS 304 stainless steel tubes subjected to symmetrical cyclic bending.…”

Experimental and Theoretical Investigation of the Response and Collapse of 316L Stainless Steel Tubes Subjected to Cyclic Bending

“…As the cyclic process continues, the ovalization keeps accumulating. A similar test result was also reported by Kyriakides and Shaw (2) for 606l-T6 aluminum and l018 steel tubes and Hsu et al (9) for titanium alloy tubes. Figure 8 shows a picture of the local buckling of the 316L stainless steel tubes under cyclic bending.…”

“…The intrinsic time measure ζ is dζ = de p ∼ (9) in which · represents the Euclidean norm. The material function (or hardening function) f (ζ) is…”

“…The tubes used by them were the same as that used by Pan et al (1) Pan and Her (8) investigated the response and stability of SUS 304 stainless steel tubes subjected to cyclic bending with different curvature-rates. Hsu et al (9) investigated the elastoplastic response and stability of titanium alloy tubes subjected cyclic bending and Lee and Pan (10) investigated the viscoplastic response and stability of titanium alloy tubes subjected cyclic bending. Lee et al (11) discussed the influence of the diameter-tothickness ratio to the response and stability of SUS 304 stainless steel tubes subjected to symmetrical cyclic bending.…”

Experimental and Theoretical Investigation of the Response and Collapse of 316L Stainless Steel Tubes Subjected to Cyclic Bending

“…Experiments and theoretical studies have been carried out on smooth tubes of various materials, such as 304 stainless steel, 310 stainless steel, 316L stainless steel, and titanium alloy pipes (ASTM B338 Grade 2). The following behaviors were studied: tubes under cyclic bending (Hsu et al 24 ; Chang and Pan 25 ), tubes under cyclic bending with different curvature rates (Pan and Her 26 ; Lee and Pan 27 ; Chang et al 28 ), tubes with different D o /t ratios under cyclic bending (Lee et al 29 ; Lee et al 30 ; Chang et al 31 ), tubes under cyclic bending with different mean curvatures (Pan and Lee 32 ), tubes under cyclic bending with different mean moments (Chang et al 33 ), and tubes under pure bending creep (Lee and Pan 34 ).…”

Mean curvature effect on the response and failure of round-hole tubes submitted to cyclic bending

Buckling life estimation of circular tubes of different materials under cyclic bending