Cyclic heat-up and damage-relevant substrate plastification of single- and bilayer coated milling inserts evaluated numerically

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Cyclic heat-up and damage-relevant substrate plastification of single- and bilayer coated milling inserts evaluated numerically. / Nemetz, Andreas; Daves, Werner; Klünsner, Thomas et al.
In: Surface & coatings technology, Vol. 360.2019, No. February, 2019, p. 39-49.

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Nemetz A, Daves W, Klünsner T, Ecker W, Schäfer J, Czettl C et al. Cyclic heat-up and damage-relevant substrate plastification of single- and bilayer coated milling inserts evaluated numerically. Surface & coatings technology. 2019;360.2019(February):39-49. doi: 10.1016/j.surfcoat.2019.01.008

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Nemetz, Andreas ; Daves, Werner ; Klünsner, Thomas et al. / Cyclic heat-up and damage-relevant substrate plastification of single- and bilayer coated milling inserts evaluated numerically. In: Surface & coatings technology. 2019 ; Vol. 360.2019, No. February. pp. 39-49.

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@article{dd2c4acb3f7b4bb8907c20d2a45ea011,
title = "Cyclic heat-up and damage-relevant substrate plastification of single- and bilayer coated milling inserts evaluated numerically",
abstract = "Milling processes are characterized by interrupted cutting, resulting in cyclic thermo-mechanical loading conditions affecting the milling tool's service life. In the current paper, a numerical method is built to predict the transient temperature and stress fields inside coated milling inserts during a dry milling application. The investigated milling tools are hard coated WC-Co hard metal milling inserts, the cut workpiece material is 42CrMo4. The thermal shielding of the substrate by three different hard coating layers, each with a thickness of 7 μm is quantitatively evaluated numerically. The compared coatings are: (i) a TiAlN single layer, (ii) a TiCN/α-Al 2 O 3 bilayer and (iii) a TiAlN/α-Al 2 O 3 bilayer. The deformation behavior and thermal properties of the hard metal substrate and the hard coatings were considered as a function of temperature by experimentally parameterized material models. A remarkable new feature of the presented model is that the simulated dry milling process includes an unprecedented number of 100 load cycles. The synergetic combination of 2D and 3D finite element models gives insight into the cyclic thermo-mechanical tool load that causes stresses and inelastic strains in the substrate. The applied modeling approach considers that the heat flux between the workpiece and the milling tool is changing as the tool heats up during milling. During successive milling cycles, a decreasing heat flux into the tool is taken into account. A comparison of hard coatings with different inherent thermal properties showed a damage-relevant reduction in substrate plasticization with decreasing thermal conductivity of the coatings. ",
author = "Andreas Nemetz and Werner Daves and Thomas Kl{\"u}nsner and Werner Ecker and Jonathan Sch{\"a}fer and Christoph Czettl and Thomas Antretter",
year = "2019",
doi = "10.1016/j.surfcoat.2019.01.008",
language = "English",
volume = "360.2019",
pages = "39--49",
journal = "Surface & coatings technology",
issn = "0257-8972",
publisher = "Elsevier",
number = "February",

}

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TY - JOUR

T1 - Cyclic heat-up and damage-relevant substrate plastification of single- and bilayer coated milling inserts evaluated numerically

AU - Nemetz, Andreas

AU - Daves, Werner

AU - Klünsner, Thomas

AU - Ecker, Werner

AU - Schäfer, Jonathan

AU - Czettl, Christoph

AU - Antretter, Thomas

PY - 2019

Y1 - 2019

N2 - Milling processes are characterized by interrupted cutting, resulting in cyclic thermo-mechanical loading conditions affecting the milling tool's service life. In the current paper, a numerical method is built to predict the transient temperature and stress fields inside coated milling inserts during a dry milling application. The investigated milling tools are hard coated WC-Co hard metal milling inserts, the cut workpiece material is 42CrMo4. The thermal shielding of the substrate by three different hard coating layers, each with a thickness of 7 μm is quantitatively evaluated numerically. The compared coatings are: (i) a TiAlN single layer, (ii) a TiCN/α-Al 2 O 3 bilayer and (iii) a TiAlN/α-Al 2 O 3 bilayer. The deformation behavior and thermal properties of the hard metal substrate and the hard coatings were considered as a function of temperature by experimentally parameterized material models. A remarkable new feature of the presented model is that the simulated dry milling process includes an unprecedented number of 100 load cycles. The synergetic combination of 2D and 3D finite element models gives insight into the cyclic thermo-mechanical tool load that causes stresses and inelastic strains in the substrate. The applied modeling approach considers that the heat flux between the workpiece and the milling tool is changing as the tool heats up during milling. During successive milling cycles, a decreasing heat flux into the tool is taken into account. A comparison of hard coatings with different inherent thermal properties showed a damage-relevant reduction in substrate plasticization with decreasing thermal conductivity of the coatings.

AB - Milling processes are characterized by interrupted cutting, resulting in cyclic thermo-mechanical loading conditions affecting the milling tool's service life. In the current paper, a numerical method is built to predict the transient temperature and stress fields inside coated milling inserts during a dry milling application. The investigated milling tools are hard coated WC-Co hard metal milling inserts, the cut workpiece material is 42CrMo4. The thermal shielding of the substrate by three different hard coating layers, each with a thickness of 7 μm is quantitatively evaluated numerically. The compared coatings are: (i) a TiAlN single layer, (ii) a TiCN/α-Al 2 O 3 bilayer and (iii) a TiAlN/α-Al 2 O 3 bilayer. The deformation behavior and thermal properties of the hard metal substrate and the hard coatings were considered as a function of temperature by experimentally parameterized material models. A remarkable new feature of the presented model is that the simulated dry milling process includes an unprecedented number of 100 load cycles. The synergetic combination of 2D and 3D finite element models gives insight into the cyclic thermo-mechanical tool load that causes stresses and inelastic strains in the substrate. The applied modeling approach considers that the heat flux between the workpiece and the milling tool is changing as the tool heats up during milling. During successive milling cycles, a decreasing heat flux into the tool is taken into account. A comparison of hard coatings with different inherent thermal properties showed a damage-relevant reduction in substrate plasticization with decreasing thermal conductivity of the coatings.

UR - http://www.scopus.com/inward/record.url?scp=85059770984&partnerID=8YFLogxK

U2 - 10.1016/j.surfcoat.2019.01.008

DO - 10.1016/j.surfcoat.2019.01.008

M3 - Article

VL - 360.2019

SP - 39

EP - 49

JO - Surface & coatings technology

JF - Surface & coatings technology

SN - 0257-8972

IS - February

ER -