On the role of damage evolution in finite element modeling of the cutting process and sensing residual stresses

Mohamed M.A. Ammar, Bijan Shirinzadeh, Hassan Elgamal, Mohamed N.A. Nasr

Research output: Contribution to journalArticleResearchpeer-review

4 Citations (Scopus)

Abstract

This study focuses on the role of the damage evolution when estimating the failure behavior of AISI 1045 steel for sensing and measuring metal cutting parameters. A total of five Lagrangian explicit models are established to investigate the effect of applying damage evolution techniques. The Johnson–Cook failure model is introduced once to fully represent damage behavior, i.e., no damage evolution is considered, and as a damage initiation criterion in the remaining approaches. A fracture energy-based model is included to model damage propagation with different evolution rates. Temperature-dependent and temperature-independent fracture energy models are also investigated. Dry orthogonal cutting and residual stresses measurements of AISI 1045 are conducted for validation. The significance of the damage evolution is investigated using honed-tool and sharp-tool models. Including the damage evolution led to a prediction of higher workpiece temperatures, plastic strains, cutting forces, and residual stresses, with no clear differences between linear and exponential evolution rates. The role of damage evolution is more evident when temperature-dependent evolution models are used.

Original languageEnglish
Article number8547
Number of pages21
JournalSensors
Volume22
Issue number21
DOIs
Publication statusPublished - Nov 2022

Keywords

  • damage modeling
  • finite element modeling (FEM)
  • machining
  • residual stresses
  • sensing

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