Limit load evaluation of inlet pigtail pipe bends with ovality under in-plane bending

Ramaswami, P.; Velmurugan, P. Senthil; Chinnasamy, Moganapriya; Rathanasamy, Rajasekar

doi:10.3139/120.111314

Materials Testing

2019

DOI: 10.3139/120.111314

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Limit load evaluation of inlet pigtail pipe bends with ovality under in-plane bending

P. Ramaswami

P. Senthil Velmurugan²,

Moganapriya Chinnasamy³

et al.

Abstract: The prediction of limit load on inlet pigtail pipe bends employed in a hydrogen reformer is one of the unresolved engineering tasks in chemical industries. This is because of the uncertainty and required extrapolation of the applicable data. In practice, the cross section of the inlet pigtail pipe bend becomes non-circular due to the bending process. This irregularity in shape extends when pipes are subjected to in-plane bending moment during plant operation. Ovality is the shape imperfection in a pipe bend co… Show more

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Comparison of three methods for measuring the bending stiffness of ultrafine metal wires

Shao

Chen

et al. 2022

Materials Testing

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Ultrafine metal wires have been widely used as structural constituents of metal meshes for electromagnetic interference shielding. To investigate the bending property of metal wires during the knitting process, the three-point bending, cantilever bending, and pure horizontal bending methods were carried out and compared. The relationships among the bending property, the twist pitch and the number of twisted wire strings were also analyzed. The specific dependence of the bending stiffness on twist pitch resulted from the internal frictional constraints, and a twist pitch of 4.5 mm was chosen as the optimized twisted parameter. The bending properties evaluated by the three methods were equally sensitive to the twist pitch, and a similar linear trend of bending stiffness with the number of twisted wire strings was found. The values of bending stiffness from the three methods were significantly different, and the descending order was the three-point bending, the cantilever bending, and the pure horizontal bending method. The correlation coefficient of the three methods was higher than 0.935, which is a strong positive correlation. From the investigation came a conclusion that the three-point bending method is more useful in realistic conditions because of its diversity and universality for various bending deformations.

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Comparison of three methods for measuring the bending stiffness of ultrafine metal wires

Shao

Chen

et al. 2022

Materials Testing

View full text Add to dashboard Cite

show abstract

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Limit load evaluation of inlet pigtail pipe bends with ovality under in-plane bending

Cited by 1 publication

References 14 publications

Comparison of three methods for measuring the bending stiffness of ultrafine metal wires

Comparison of three methods for measuring the bending stiffness of ultrafine metal wires

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