Research on precision forging law of complicated blade by using 3D FE simulation and physical modeling

M. Zhan; H. Yang; Y. L. Liu

doi:10.4028/www.scientific.net/msf.471-472.839

Research on precision forging law of complicated blade by using 3D FE simulation and physical modeling

M. Zhan, H. Yang, Y. L. Liu

School of Materials Sience and Engineering

Northwestern Polytechnical University Xian

Research output: Contribution to journal › Conference article › peer-review

1 Scopus citations

Abstract

Research on precision forming laws of complicated blade has been a challenging issue on international frontiers of plastic forming areas. The precision forging laws of the blade with a damper platform have been obtained by using 3D FE simulation and physical modeling. The laws involve in the deforming characteristics of the tenon, damper platform, middle blade body, and tip blade body, such as the unevenness of deformation and material flow, the branch-flow of material, material flow characteristic of the blade body and rotation forming characteristic of the damper platform. The research may serve as a guide to the optimization design of relevant process and dies.

Original language	English
Pages (from-to)	839-843
Number of pages	5
Journal	Materials Science Forum
Volume	471-472
DOIs	https://doi.org/10.4028/www.scientific.net/msf.471-472.839
State	Published - 2004
Event	11th International Manufacturing Conference - Advances in Materials Manufacturing Science and Technology. - Jinan, China Duration: 18 Sep 2004 → 20 Sep 2004

Keywords

3D FE simulation
Blade with a damper platform
Physical modeling
Precision forging

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title = "Research on precision forging law of complicated blade by using 3D FE simulation and physical modeling",

abstract = "Research on precision forming laws of complicated blade has been a challenging issue on international frontiers of plastic forming areas. The precision forging laws of the blade with a damper platform have been obtained by using 3D FE simulation and physical modeling. The laws involve in the deforming characteristics of the tenon, damper platform, middle blade body, and tip blade body, such as the unevenness of deformation and material flow, the branch-flow of material, material flow characteristic of the blade body and rotation forming characteristic of the damper platform. The research may serve as a guide to the optimization design of relevant process and dies.",

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volume = "471-472",

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journal = "Materials Science Forum",

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TY - JOUR

T1 - Research on precision forging law of complicated blade by using 3D FE simulation and physical modeling

AU - Zhan, M.

AU - Yang, H.

AU - Liu, Y. L.

PY - 2004

Y1 - 2004

N2 - Research on precision forming laws of complicated blade has been a challenging issue on international frontiers of plastic forming areas. The precision forging laws of the blade with a damper platform have been obtained by using 3D FE simulation and physical modeling. The laws involve in the deforming characteristics of the tenon, damper platform, middle blade body, and tip blade body, such as the unevenness of deformation and material flow, the branch-flow of material, material flow characteristic of the blade body and rotation forming characteristic of the damper platform. The research may serve as a guide to the optimization design of relevant process and dies.

AB - Research on precision forming laws of complicated blade has been a challenging issue on international frontiers of plastic forming areas. The precision forging laws of the blade with a damper platform have been obtained by using 3D FE simulation and physical modeling. The laws involve in the deforming characteristics of the tenon, damper platform, middle blade body, and tip blade body, such as the unevenness of deformation and material flow, the branch-flow of material, material flow characteristic of the blade body and rotation forming characteristic of the damper platform. The research may serve as a guide to the optimization design of relevant process and dies.

KW - 3D FE simulation

KW - Blade with a damper platform

KW - Physical modeling

KW - Precision forging

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SN - 0255-5476

VL - 471-472

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JO - Materials Science Forum

JF - Materials Science Forum

T2 - 11th International Manufacturing Conference - Advances in Materials Manufacturing Science and Technology.

Y2 - 18 September 2004 through 20 September 2004

ER -

Research on precision forging law of complicated blade by using 3D FE simulation and physical modeling

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Keywords

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