Geometrical shape assessment of additively manufactured features by Continuous Liquid Interface Production, vat photopolymerization method

A. Davoudinejad*, A. K. Jessen, S. D. Farahani, N. Franke, D. B. Pedersen, G. Tosello

*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceedingConference abstract in proceedingsResearchpeer-review

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Abstract

Additive Manufacturing (AM) is a notable procedure for direct production of miniaturized polymer components, mainly due to the ability of the process to produce complex geometries with time and cost effective iteration cycles in the development of new plastic products. This study evaluate the capability of the vat photopolymerization in terms of geometry, when printing features of different sizes and shape. Continuous Liquid Interface Production (CLIP) technology was used for printing the features which is a new method to produce monolithic polymer parts at high speed. For this purpose, two test artifact specimens designed with micro features of different geometries and printed in different batches and evaluated the variability of the results in a single and in various prints.
Original languageEnglish
Title of host publicationProceedings of the 19th International Conference and Exhibition (EUSPEN 2019)
EditorsC. Nisbet, R. K. Leach , D. Billington, D. Phillips
PublisherThe European Society for Precision Engineering and Nanotechnology
Publication date2019
Pages116-117
ISBN (Electronic)978-099577514-5
Publication statusPublished - 2019
Eventeuspen's 19th International Conference & Exhibition - Bilbao, Spain
Duration: 3 Jun 20197 Jun 2019

Conference

Conferenceeuspen's 19th International Conference & Exhibition
CountrySpain
CityBilbao
Period03/06/201907/06/2019

Keywords

  • Additive Manufacturing
  • Vat Photopolymerization
  • Micro Manufacturing
  • Polymer

Cite this

Davoudinejad, A., Jessen, A. K., Farahani, S. D., Franke, N., Pedersen, D. B., & Tosello, G. (2019). Geometrical shape assessment of additively manufactured features by Continuous Liquid Interface Production, vat photopolymerization method. In C. Nisbet, R. K. Leach , D. Billington, & D. Phillips (Eds.), Proceedings of the 19th International Conference and Exhibition (EUSPEN 2019) (pp. 116-117). The European Society for Precision Engineering and Nanotechnology.
Davoudinejad, A. ; Jessen, A. K. ; Farahani, S. D. ; Franke, N. ; Pedersen, D. B. ; Tosello, G. / Geometrical shape assessment of additively manufactured features by Continuous Liquid Interface Production, vat photopolymerization method. Proceedings of the 19th International Conference and Exhibition (EUSPEN 2019). editor / C. Nisbet ; R. K. Leach ; D. Billington ; D. Phillips . The European Society for Precision Engineering and Nanotechnology, 2019. pp. 116-117
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abstract = "Additive Manufacturing (AM) is a notable procedure for direct production of miniaturized polymer components, mainly due to the ability of the process to produce complex geometries with time and cost effective iteration cycles in the development of new plastic products. This study evaluate the capability of the vat photopolymerization in terms of geometry, when printing features of different sizes and shape. Continuous Liquid Interface Production (CLIP) technology was used for printing the features which is a new method to produce monolithic polymer parts at high speed. For this purpose, two test artifact specimens designed with micro features of different geometries and printed in different batches and evaluated the variability of the results in a single and in various prints.",
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Davoudinejad, A, Jessen, AK, Farahani, SD, Franke, N, Pedersen, DB & Tosello, G 2019, Geometrical shape assessment of additively manufactured features by Continuous Liquid Interface Production, vat photopolymerization method. in C Nisbet, RK Leach , D Billington & D Phillips (eds), Proceedings of the 19th International Conference and Exhibition (EUSPEN 2019). The European Society for Precision Engineering and Nanotechnology, pp. 116-117, euspen's 19th International Conference & Exhibition , Bilbao, Spain, 03/06/2019.

Geometrical shape assessment of additively manufactured features by Continuous Liquid Interface Production, vat photopolymerization method. / Davoudinejad, A.; Jessen, A. K.; Farahani, S. D. ; Franke, N. ; Pedersen, D. B.; Tosello, G.

Proceedings of the 19th International Conference and Exhibition (EUSPEN 2019). ed. / C. Nisbet; R. K. Leach ; D. Billington; D. Phillips . The European Society for Precision Engineering and Nanotechnology, 2019. p. 116-117.

Research output: Chapter in Book/Report/Conference proceedingConference abstract in proceedingsResearchpeer-review

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AB - Additive Manufacturing (AM) is a notable procedure for direct production of miniaturized polymer components, mainly due to the ability of the process to produce complex geometries with time and cost effective iteration cycles in the development of new plastic products. This study evaluate the capability of the vat photopolymerization in terms of geometry, when printing features of different sizes and shape. Continuous Liquid Interface Production (CLIP) technology was used for printing the features which is a new method to produce monolithic polymer parts at high speed. For this purpose, two test artifact specimens designed with micro features of different geometries and printed in different batches and evaluated the variability of the results in a single and in various prints.

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Davoudinejad A, Jessen AK, Farahani SD, Franke N, Pedersen DB, Tosello G. Geometrical shape assessment of additively manufactured features by Continuous Liquid Interface Production, vat photopolymerization method. In Nisbet C, Leach RK, Billington D, Phillips D, editors, Proceedings of the 19th International Conference and Exhibition (EUSPEN 2019). The European Society for Precision Engineering and Nanotechnology. 2019. p. 116-117