Effect of rotation speed on temperature field and axial shortening of inertia friction welded GH4169 joints by numerical simulation

Liang Chen; Wen Ya Li; Jing Long Li

doi:10.1007/s12204-011-1143-2

Effect of rotation speed on temperature field and axial shortening of inertia friction welded GH4169 joints by numerical simulation

Liang Chen, Wen Ya Li, Jing Long Li

School of Materials Sience and Engineering

Northwestern Polytechnical University Xian

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

A 2D finite element model was established for inertia friction welding of GH4169 nickel-base superalloy based on the ABAQUS environment. The remeshing and map solution techniques were adopted to solve the problem of element distortion. The effect of rotation speed on the temperature field and axial shortening of joints was investigated. The results show that the interface temperature increases rapidly to higher than 900? within 1 s. and then, it increases slowly to a quasi-stable value. The axial shortening begins to augment quickly when a uniform interface temperature field has formed and the plasticized material is extruded from the interface to form an obvious flash. The rotation speed of the flywheel controls the welding process and has a significant influence on the temperature evolution and axial shortening of joints.

Original language	English
Pages (from-to)	277-280
Number of pages	4
Journal	Journal of Shanghai Jiaotong University (Science)
Volume	16
Issue number	3
DOIs	https://doi.org/10.1007/s12204-011-1143-2
State	Published - Jun 2011

Keywords

Inertia friction welding
Map solution
Numerical simulation
Temperature field

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10.1007/s12204-011-1143-2

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title = "Effect of rotation speed on temperature field and axial shortening of inertia friction welded GH4169 joints by numerical simulation",

abstract = "A 2D finite element model was established for inertia friction welding of GH4169 nickel-base superalloy based on the ABAQUS environment. The remeshing and map solution techniques were adopted to solve the problem of element distortion. The effect of rotation speed on the temperature field and axial shortening of joints was investigated. The results show that the interface temperature increases rapidly to higher than 900? within 1 s. and then, it increases slowly to a quasi-stable value. The axial shortening begins to augment quickly when a uniform interface temperature field has formed and the plasticized material is extruded from the interface to form an obvious flash. The rotation speed of the flywheel controls the welding process and has a significant influence on the temperature evolution and axial shortening of joints.",

keywords = "Inertia friction welding, Map solution, Numerical simulation, Temperature field",

author = "Liang Chen and Li, {Wen Ya} and Li, {Jing Long}",

year = "2011",

month = jun,

doi = "10.1007/s12204-011-1143-2",

language = "英语",

volume = "16",

pages = "277--280",

journal = "Journal of Shanghai Jiaotong University (Science)",

issn = "1007-1172",

publisher = "Shanghai Jiaotong University",

number = "3",

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T1 - Effect of rotation speed on temperature field and axial shortening of inertia friction welded GH4169 joints by numerical simulation

AU - Chen, Liang

AU - Li, Wen Ya

AU - Li, Jing Long

PY - 2011/6

Y1 - 2011/6

N2 - A 2D finite element model was established for inertia friction welding of GH4169 nickel-base superalloy based on the ABAQUS environment. The remeshing and map solution techniques were adopted to solve the problem of element distortion. The effect of rotation speed on the temperature field and axial shortening of joints was investigated. The results show that the interface temperature increases rapidly to higher than 900? within 1 s. and then, it increases slowly to a quasi-stable value. The axial shortening begins to augment quickly when a uniform interface temperature field has formed and the plasticized material is extruded from the interface to form an obvious flash. The rotation speed of the flywheel controls the welding process and has a significant influence on the temperature evolution and axial shortening of joints.

AB - A 2D finite element model was established for inertia friction welding of GH4169 nickel-base superalloy based on the ABAQUS environment. The remeshing and map solution techniques were adopted to solve the problem of element distortion. The effect of rotation speed on the temperature field and axial shortening of joints was investigated. The results show that the interface temperature increases rapidly to higher than 900? within 1 s. and then, it increases slowly to a quasi-stable value. The axial shortening begins to augment quickly when a uniform interface temperature field has formed and the plasticized material is extruded from the interface to form an obvious flash. The rotation speed of the flywheel controls the welding process and has a significant influence on the temperature evolution and axial shortening of joints.

KW - Inertia friction welding

KW - Map solution

KW - Numerical simulation

KW - Temperature field

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VL - 16

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JO - Journal of Shanghai Jiaotong University (Science)

JF - Journal of Shanghai Jiaotong University (Science)

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ER -

Effect of rotation speed on temperature field and axial shortening of inertia friction welded GH4169 joints by numerical simulation

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