Investigation on influences of initial residual stress on thin-walled part machining deformation based on a semi-analytical model

[Display omitted] The manufacturing accuracy of the thin-walled parts is significantly affected by the residual stress in the blank and the resulting machining deformation. In recent years, the prediction and control of the machining deformation have received extensive attentions. A semi-analytical...

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Vydáno v:Journal of materials processing technology Ročník 262; s. 437 - 448
Hlavní autoři: Gao, Hanjun, Zhang, Yidu, Wu, Qiong, Li, Bianhong
Médium: Journal Article
Jazyk:angličtina
Vydáno: Amsterdam Elsevier B.V 01.12.2018
Elsevier BV
Témata:
Computer simulation
Crystal surfaces
Deformation
Deformation analysis
Deformation effects
Equivalence
Equivalent bending stiffness
Finite element analysis
Finite element method
Initial residual stresses
Machining
Machining deformation
Materials science
Mathematical analysis
Mathematical models
Model accuracy
Prediction models
Residual stress
Semi-analytical model
Stiffness
Thin-walled parts
Initial residual stresses
Machining deformation
Semi-analytical model
Equivalent bending stiffness
Thin-walled parts
ISSN:0924-0136, 1873-4774
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Shrnutí:[Display omitted] The manufacturing accuracy of the thin-walled parts is significantly affected by the residual stress in the blank and the resulting machining deformation. In recent years, the prediction and control of the machining deformation have received extensive attentions. A semi-analytical machining deformation prediction model is proposed for the thin-walled parts in terms of the equivalent bending stiffness calculated by finite element method (FEM) simulation and theory of plates and shells. Machining deformations of seven typical study cases are predicted by the semi-analytical model. Corresponding experiments and FEM simulations are conducted to validate the proposed model. Then, the influences of the initial residual stress and equivalent bending stiffness on the machining deformation are investigated based on the quantitative results of the proposed model, which is difficult to be obtained by the previous FE models. The results suggests that 1) improving the bending stiffness of the part can effectively reduce the machining deformation; 2) decreasing the stresses in the top part of the blank and in the length direction is more advantageous to reduce the deformation than other parts and directions; 3) the final machining deformation is basically determined by the residual stress within a certain thickness under the blank surface when the residual stress symmetrically distributes along the mid-plane in thickness direction.
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ISSN:0924-0136
1873-4774
DOI:10.1016/j.jmatprotec.2018.04.009