Transverse Bending Characteristics in U-channel Forming of Tailor Rolled Blank

Research on the formability of tailor rolled blank (TRB) is of good practical significance and application value because of the enormous potential of TRB in the aspect of automobile lightweight. However, the forming of TRB is problematic because of the varying properties; especially, springback is a...

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Bibliographic Details
Published inJournal of iron and steel research, international Vol. 23; no. 12; pp. 1249 - 1254
Main Authors ZHANG, Hua-wei, GUAN, Ying-ping, WU, Jia-lu, LIU, Xiang-hua
Format Journal Article
LanguageEnglish
Published Singapore Elsevier Ltd 01.12.2016
Springer Singapore
Subjects
annealing
Applied and Technical Physics
Engineering
Machines
Manufacturing
Materials Engineering
Materials Science
Metallic Materials
Metallurgy and Metal Working
Physical Chemistry
Processes
springback
tailor rolled blank
thickness transition zone
transverse bending
TRB
U-channel
弯曲回弹
弯曲特性
成形性能
裁缝
轧坯
通道
U-channel
transverse bending
thickness transition zone
annealing
springback
tailor rolled blank
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ISSN1006-706X
2210-3988
DOI10.1016/S1006-706X(16)30184-4

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Summary:Research on the formability of tailor rolled blank (TRB) is of good practical significance and application value because of the enormous potential of TRB in the aspect of automobile lightweight. However, the forming of TRB is problematic because of the varying properties; especially, springback is a main challenge. The transverse bending (bending axis is perpendicular to the rolling direction) of TRB U-channel was studied through simulation and experiment. The forming characteristics of TRB U-channel during transverse bending were analyzed. The mechanisms of forming defects, including bending springback and thickness transition zone (TTZ) movement, were revealed. On this basis, effects of blank geometric parameters on springback and TTZ movement were discussed. The results indicate that springback and TTZ movement happen during transverse bending of TRB U-channel. Nonuniform stress distribution is the most fundamental reason for the occurrence of springback of TRB during transverse bending. Annealing can eliminate nonuniform stress distribution, and thus diminish springback of TRB, especially springback on the thinner side. Therefore, springback of the whole TRB becomes more uniform. However, annealing can increase the TTZ movement. Blank thickness and TTZ position are the main factors affecting the formability of TRB U-channel during transverse bending.
Bibliography:11-3678/TF
tailor rolled blank; transverse bending; springback; U-channel; annealing; thickness transition zone
Research on the formability of tailor rolled blank (TRB) is of good practical significance and application value because of the enormous potential of TRB in the aspect of automobile lightweight. However, the forming of TRB is problematic because of the varying properties; especially, springback is a main challenge. The transverse bending (bending axis is perpendicular to the rolling direction) of TRB U channel was studied through simulation and experiment. The forming characteristics of TRB U channel during transverse bending were analyzed. The mechanisms of forming defects, including bending springback and thickness transition zone (TTZ) movement, were revealed. On this basis, effects of blank geometric parameters on springbaek and TTZ movement were discussed. The results indicate that springback and TTZ movement happen during transverse bending of TRB U-channel. Nonuni form stress distribution is the most fundamental reason for the occurrence of springback of TRB during transverse bending. Annealing can eliminate nonuniform stress distribution, and thus diminish springbaek of TRB, especially springback on the thinner side. Therefore, springback of the whole TRB becomes more uniform. However, annealing can increase the TTZ movement. Blank thickness and TTZ position are the main factors affecting the formability of TRB U-channel during transverse bending.
ISSN:1006-706X
2210-3988
DOI:10.1016/S1006-706X(16)30184-4