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プロフィール詳細
プロジェクトを作成
★★★★★
☆☆☆☆☆
Dr. Tone D.に依頼
United States

ChE PhD, Expert in FEA, Thermomechanical and Thermochemical Characterization

プロフィール概要
専門分野
サービス
Writing Technical Writing
Research Fact Checking, Scientific and Technical Research
Consulting Scientific and Technical Consulting
Data & AI Data Visualization, Data Processing, Data Insights
職務経験

Research and Development Engineer

Carbon Composites Inc.

1月 2023 - 6月 2024

Senior Validation Specialist

MilliporeSigma

1月 2021 - 9月 2022

学歴

PhD (Chemical Engineering)

Worcester Polytechnic Institute

8月 2014 - 現在

Bachelor of Science (Chemical Engineering)

University of New Hampshire

8月 2010 - 5月 2014

認定資格
  • 認定資格の詳細は未入力です。
出版物
JOURNAL ARTICLE
Tone D’Amico, Amy M. Peterson(2020). Bead parameterization of desktop and room-scale material extrusion additive manufacturing: How print speed and thermal properties affect heat transfer . Additive Manufacturing. 34. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 101239. Elsevier {BV}
Tone D’Amico, Connor Barrett, Joseph Presing, Amy M. Peterson(2019). Micromechanical modeling of irreversible thermal strain . Additive Manufacturing. 27. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 91--98. Elsevier {BV}
Anthony D’Amico and Amy M. Peterson(2018). An adaptable FEA simulation of material extrusion additive manufacturing heat transfer in 3D . Additive Manufacturing. 21. Microsoft.AspNetCore.Mvc.Localization.LocalizedHtmlString 422 - 430.
Effect of layer thickness on irreversible thermal expansion and interlayer strength in fused deposition modeling @article{doi:10.1108/RPJ-05-2016-0077, author= {Anthony A. D’Amico and Analise Debaie and Amy M. Peterson}, title= {Effect of layer thickness on irreversible thermal expansion and interlayer strength in fused deposition modeling}, journal= {Rapid Prototyping Journal}, volume= {23}, number= {5}, pages= {943-953}, year= {2017}, doi= {10.1108/RPJ-05-2016-0077}, URL= {https://doi.org/10.1108/RPJ-05-2016-0077 }, eprint= {https://doi.org/10.1108/RPJ-05-2016-0077 }, abstract= {Purpose The aim of this paper is to examine the impact of layer thickness on irreversible thermal expansion, residual stress and mechanical properties of additively manufactured parts. Design/methodology/approach Samples were printed at several layer thicknesses, and their irreversible thermal expansion, tensile strength and flexural strength were determined. Findings Irreversible thermal strain increases with decreasing layer thickness, up to 22 per cent strain. Tensile and flexural strengths exhibited a peak at a layer thickness of 200 μm although the maximum was not statistically significant at a 95 per cent confidence interval. Tensile strength was 54 to 97 per cent of reported values for injection molded acrylonitrile butadiene styrene (ABS) and 29 to 73 per cent of those reported for bulk ABS. Flexural strength was 18 to 41 per cent of reported flexural strength for bulk ABS. Practical implications The large irreversible thermal strain exhibited that corresponding residual stresses could lead to failure of additively manufactured parts over time. Additionally, the observed irreversible thermal strains could enable thermally responsive shape in additively manufactured parts. Variation in mechanical properties with layer thickness will also affect manufactured parts. Originality/value Tailorable irreversible thermal strain of this magnitude has not been previously reported for additively manufactured parts. This strain occurs in parts made with both high-end and consumer grade fused deposition modeling machines. Additionally, the impact of layer thickness on tensile and flexural properties of additively manufactured parts has received limited attention in the literature. }} . Rapid Prototyping Journal.