Laser cutting of thick-section circular blanks: Thermal stress prediction and microstructural analysis

Syed Sohail Akhtar

doi:10.1007/s00170-013-5594-5

Laser cutting of thick-section circular blanks: Thermal stress prediction and microstructural analysis

Syed Sohail Akhtar^*

^*Corresponding author for this work

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

9 Scopus citations

Abstract

Laser cutting of thick-section circular mild-steel blanks of 10 mm thickness is examined. Thermal and stress fields developed in the cutting zone are predicted using finite element method and the simulation conditions are selected in line with the experimental parameters. An experiment is carried out to assess the geometric features of the cut surfaces. The morphology of the cut sections are examined using optical and scanning electron microscopes and energy dispersive spectroscopy is carried out for elemental composition of the cut surface. It is found that laser cutting of thick steel blanks results in substantial conduction loss from the cutting zone, which results in high-temperature gradients and large stress levels in the cutting section. The cut edge features such as local dross attachment, striation patterns, and microcrack formation in the cut section are also examined.

Original language	English
Pages (from-to)	1345-1358
Number of pages	14
Journal	International Journal of Advanced Manufacturing Technology
Volume	71
Issue number	5-8
DOIs	https://doi.org/10.1007/s00170-013-5594-5
State	Published - Mar 2014

Keywords

Finite element analysis
Laser
Microstructure
Residual stress
Thick section

ASJC Scopus subject areas

Control and Systems Engineering
Software
Mechanical Engineering
Computer Science Applications
Industrial and Manufacturing Engineering

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10.1007/s00170-013-5594-5

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title = "Laser cutting of thick-section circular blanks: Thermal stress prediction and microstructural analysis",

abstract = "Laser cutting of thick-section circular mild-steel blanks of 10 mm thickness is examined. Thermal and stress fields developed in the cutting zone are predicted using finite element method and the simulation conditions are selected in line with the experimental parameters. An experiment is carried out to assess the geometric features of the cut surfaces. The morphology of the cut sections are examined using optical and scanning electron microscopes and energy dispersive spectroscopy is carried out for elemental composition of the cut surface. It is found that laser cutting of thick steel blanks results in substantial conduction loss from the cutting zone, which results in high-temperature gradients and large stress levels in the cutting section. The cut edge features such as local dross attachment, striation patterns, and microcrack formation in the cut section are also examined.",

keywords = "Finite element analysis, Laser, Microstructure, Residual stress, Thick section",

author = "Akhtar, \{Syed Sohail\}",

year = "2014",

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language = "English",

volume = "71",

pages = "1345--1358",

journal = "International Journal of Advanced Manufacturing Technology",

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T1 - Laser cutting of thick-section circular blanks

T2 - Thermal stress prediction and microstructural analysis

AU - Akhtar, Syed Sohail

PY - 2014/3

Y1 - 2014/3

N2 - Laser cutting of thick-section circular mild-steel blanks of 10 mm thickness is examined. Thermal and stress fields developed in the cutting zone are predicted using finite element method and the simulation conditions are selected in line with the experimental parameters. An experiment is carried out to assess the geometric features of the cut surfaces. The morphology of the cut sections are examined using optical and scanning electron microscopes and energy dispersive spectroscopy is carried out for elemental composition of the cut surface. It is found that laser cutting of thick steel blanks results in substantial conduction loss from the cutting zone, which results in high-temperature gradients and large stress levels in the cutting section. The cut edge features such as local dross attachment, striation patterns, and microcrack formation in the cut section are also examined.

AB - Laser cutting of thick-section circular mild-steel blanks of 10 mm thickness is examined. Thermal and stress fields developed in the cutting zone are predicted using finite element method and the simulation conditions are selected in line with the experimental parameters. An experiment is carried out to assess the geometric features of the cut surfaces. The morphology of the cut sections are examined using optical and scanning electron microscopes and energy dispersive spectroscopy is carried out for elemental composition of the cut surface. It is found that laser cutting of thick steel blanks results in substantial conduction loss from the cutting zone, which results in high-temperature gradients and large stress levels in the cutting section. The cut edge features such as local dross attachment, striation patterns, and microcrack formation in the cut section are also examined.

KW - Finite element analysis

KW - Laser

KW - Microstructure

KW - Residual stress

KW - Thick section

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JF - International Journal of Advanced Manufacturing Technology

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ER -

Laser cutting of thick-section circular blanks: Thermal stress prediction and microstructural analysis

Abstract

Keywords

ASJC Scopus subject areas

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