Machining using a diamond-coated cutting tool: finite element simulations and experiments

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dc.contributor Chou, Y. Kevin
dc.contributor Acoff, Viola L.
dc.contributor Barkey, Mark E.
dc.contributor Fonseca, Daniel J.
dc.contributor Ladani, Leila J.
dc.contributor.advisor Chou, Y. Kevin
dc.contributor.author Qin, Feng
dc.date.accessioned 2017-03-01T16:25:00Z
dc.date.available 2017-03-01T16:25:00Z
dc.date.issued 2012
dc.identifier.other u0015_0000001_0000854
dc.identifier.other QIN_alatus_0004D_11074
dc.identifier.uri https://ir.ua.edu/handle/123456789/1357
dc.description Electronic Thesis or Dissertation
dc.description.abstract Chemical vapor deposition (CVD) diamond-coated tools have the advantage of a low cost and flexibility in fabrications when compared with sintered polycrystalline diamond (PCD) tools in machining lightweight high-strength materials. However, coating-substrate interface delaminations remain a major technical barrier. Further, the complex effects of the tool geometry and the deposition residual stress, as well the machining conditions on the tool performance, have hindered the industrial applications of CVD diamond-coated tools. The objectives of this research are: (1) to develop finite element (FE) models of cutting simulations including deposition residual stresses for investigating tool edge radius effects on diamond-coated tool stress evolutions from depositions to machining; (2) to study diamond-coated tool performance in machining Al-Si alloys and Al-matrix composites with various cutting conditions; (3) to implement a cohesive zone interface in a diamond-coated tool for two-dimensional (2D) cutting simulations. The research methods include: (1) coupled thermo-mechanical finite element modeling of cutting simulations, including the deposition residual stress, for tool performance evaluations and tool stress evolutions; (2) machining of A390 alloy and A359/SiC-20p composite workpieces with a force sensor and tool wear evaluations at different conditions; and (3) incorporating a traction-separation law as the interface behavior in the FE cutting simulations for coating delamination analysis. The major findings are summarized as follows: (1) In gentle cutting, deposition residual stresses remain dominant, but change noticeably at a large uncut chip thickness. (2) 2D FE results of the cutting simulation are compared with the machining experiments. The difference between simulations and experiments is acceptable. (3) Increasing the edge radius will increase cutting forces; however, this increasing rate decreases at a higher feed. The combined effects of the tool geometry and cutting conditions result in complex wear behavior of diamond-coated tools. (4) The cutting simulations incorporating a cohesive-zone interface in a diamond-coated cutting tool demonstrate that the interface fracture energy is the major cause of coating delaminations. Furthermore, a larger uncut chip thickness tends to result in coating delaminations.
dc.format.extent 237 p.
dc.format.medium electronic
dc.format.mimetype application/pdf
dc.language English
dc.language.iso en_US
dc.publisher University of Alabama Libraries
dc.relation.ispartof The University of Alabama Electronic Theses and Dissertations
dc.relation.ispartof The University of Alabama Libraries Digital Collections
dc.relation.hasversion born digital
dc.rights All rights reserved by the author unless otherwise indicated.
dc.subject.other Mechanical engineering
dc.title Machining using a diamond-coated cutting tool: finite element simulations and experiments
dc.type thesis
dc.type text
etdms.degree.department University of Alabama. Dept. of Mechanical Engineering
etdms.degree.discipline Mechanical Engineering
etdms.degree.grantor The University of Alabama
etdms.degree.level doctoral
etdms.degree.name Ph.D.


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