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Effect of Thermal and Mechanical Deformation of Metamaterial FDM Components

Research output: Contribution in Book/Report/Proceedings - With ISBN/ISSNConference contribution/Paperpeer-review

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Effect of Thermal and Mechanical Deformation of Metamaterial FDM Components. / Celik, H Kursat; Tan, Yap; Seviour, Rebecca et al.
US _ TURKEY Workshop on Rapid Technologies (RapidTech 2009). 2009. p. 83-88.

Research output: Contribution in Book/Report/Proceedings - With ISBN/ISSNConference contribution/Paperpeer-review

Harvard

Celik, HK, Tan, Y, Seviour, R & Rennie, A 2009, Effect of Thermal and Mechanical Deformation of Metamaterial FDM Components. in US _ TURKEY Workshop on Rapid Technologies (RapidTech 2009). pp. 83-88. <http://www.rapidtech.itu.edu.tr/programme2.php>

APA

Celik, H. K., Tan, Y., Seviour, R., & Rennie, A. (2009). Effect of Thermal and Mechanical Deformation of Metamaterial FDM Components. In US _ TURKEY Workshop on Rapid Technologies (RapidTech 2009) (pp. 83-88) http://www.rapidtech.itu.edu.tr/programme2.php

Vancouver

Celik HK, Tan Y, Seviour R, Rennie A. Effect of Thermal and Mechanical Deformation of Metamaterial FDM Components. In US _ TURKEY Workshop on Rapid Technologies (RapidTech 2009). 2009. p. 83-88

Author

Celik, H Kursat ; Tan, Yap ; Seviour, Rebecca et al. / Effect of Thermal and Mechanical Deformation of Metamaterial FDM Components. US _ TURKEY Workshop on Rapid Technologies (RapidTech 2009). 2009. pp. 83-88

Bibtex

@inproceedings{566ce5bb94c0435a847625767ad225ca,
title = "Effect of Thermal and Mechanical Deformation of Metamaterial FDM Components",
abstract = "At Lancaster University, research is currently investigating the use of rapid manufacturing (RM) to realise metamaterials, although key to the success of this project is the development of an understanding of how coated RM parts deform under thermal and mechanical stress. The research in this paper presents a comparison of the thermal and mechanical deformation behaviour of RM coated metamaterials components from a numerical context. The research uses the design of a simple metamaterial unit cell as a test model for both the experimental and finite element method (FEM). The investigation of deformation behaviour of sample Fused Deposition Modelling (FDM) parts manufactured in different orientations and simulated using commercial FEM code means that the FEM analysis can be utilized for design verification of FDM parts. This research contributes to further research into the development of RM metamaterials, specifically design analysis and verification tools for RM materials.",
keywords = "Fused Deposition Modeling, Rapid Manufacturing, Metamaterials, Finite Element Method",
author = "Celik, {H Kursat} and Yap Tan and Rebecca Seviour and Allan Rennie",
note = "September 24-25, 2009 Management Faculty Istanbul Technical University Macka, Istanbul, Turkey",
year = "2009",
month = sep,
language = "English",
isbn = "9789944629201",
pages = "83--88",
booktitle = "US _ TURKEY Workshop on Rapid Technologies (RapidTech 2009)",

}

RIS

TY - GEN

T1 - Effect of Thermal and Mechanical Deformation of Metamaterial FDM Components

AU - Celik, H Kursat

AU - Tan, Yap

AU - Seviour, Rebecca

AU - Rennie, Allan

N1 - September 24-25, 2009 Management Faculty Istanbul Technical University Macka, Istanbul, Turkey

PY - 2009/9

Y1 - 2009/9

N2 - At Lancaster University, research is currently investigating the use of rapid manufacturing (RM) to realise metamaterials, although key to the success of this project is the development of an understanding of how coated RM parts deform under thermal and mechanical stress. The research in this paper presents a comparison of the thermal and mechanical deformation behaviour of RM coated metamaterials components from a numerical context. The research uses the design of a simple metamaterial unit cell as a test model for both the experimental and finite element method (FEM). The investigation of deformation behaviour of sample Fused Deposition Modelling (FDM) parts manufactured in different orientations and simulated using commercial FEM code means that the FEM analysis can be utilized for design verification of FDM parts. This research contributes to further research into the development of RM metamaterials, specifically design analysis and verification tools for RM materials.

AB - At Lancaster University, research is currently investigating the use of rapid manufacturing (RM) to realise metamaterials, although key to the success of this project is the development of an understanding of how coated RM parts deform under thermal and mechanical stress. The research in this paper presents a comparison of the thermal and mechanical deformation behaviour of RM coated metamaterials components from a numerical context. The research uses the design of a simple metamaterial unit cell as a test model for both the experimental and finite element method (FEM). The investigation of deformation behaviour of sample Fused Deposition Modelling (FDM) parts manufactured in different orientations and simulated using commercial FEM code means that the FEM analysis can be utilized for design verification of FDM parts. This research contributes to further research into the development of RM metamaterials, specifically design analysis and verification tools for RM materials.

KW - Fused Deposition Modeling

KW - Rapid Manufacturing

KW - Metamaterials

KW - Finite Element Method

M3 - Conference contribution/Paper

SN - 9789944629201

SP - 83

EP - 88

BT - US _ TURKEY Workshop on Rapid Technologies (RapidTech 2009)

ER -