Investigation of thermophysical properties of heat-insulating barrier manufactured by incremental rapid prototyping method
Vol 35 No 298 (1) (2018), Articles
Vol 35 No 298 (1) (2018)

Investigation of thermophysical properties of heat-insulating barrier manufactured by incremental rapid prototyping method

Articles
https://doi.org/10.7862/rm.2018.02
Published April 28, 2018
Paweł Gil
Rzeszow University of Technology, 12 Powstańców Warszawy Ave., 35-959 Rzeszów, Poland
https://orcid.org/0000-0001-9931-3012
Maria Tychanicz
Rzeszow University of Technology, Poland
https://orcid.org/0000-0003-4312-2772
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Keywords

rapid prototyping
FDM technology
thermal conductivity
3D printing

How to Cite

Gil, P., & Tychanicz, M. (2018). Investigation of thermophysical properties of heat-insulating barrier manufactured by incremental rapid prototyping method. Advances in Mechanical and Materials Engineering, 35(298 (1), 19-28. https://doi.org/10.7862/rm.2018.02
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Abstract

This paper presents the results of experimental investigation of thermophysical properties of material manufactured with 3D printing technology with the use of fused deposition modelling (FDM) method. Cylindrically shaped samples with a diameter of 50.8 mm and with various fill density (from 10 to 100%) were prepared. The investigated material was PLA (polylactic acid, polylactide). The investigation was carried out in order to determine the density, thermal conductivity, thermal diffusivity and specific heat of tested material. The main aim of this paper was to determine the influence of fill density on thermal conductivity. The results can be useful in designing thermal insulation manufactured with rapid prototyping methods, operating in relative low temperature conditions (< 100°C).

https://doi.org/10.7862/rm.2018.02
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References

1. Carneiro O.S., Silva A.F., Gomes R.: Fused deposition modeling with polypropylene, Materials Design, 83 (2015) 768-776.
2. Dawound M., Taha I., Ebeid Samy J.: Mechanical behaviour of ABS: An experimental study using FDM and injection moulding techniques, J. Manuf. Proc., 21 (2016) 39-45.
3. Weng Z., Wang J., Senthil T., Wu L.: Mechanical and thermal properties of ABS/montmorillonite nanocomposites for fused deposition modeling 3D printing, Materials Design, 102 (2016) 276-283.
4. Drummer D., Cifuentes-Cuėllar S., Rietzel D.: Suitability of PLA/TCP for fused deposition modeling, Rapid Prototyping J., 18 (2012) 500-507.
5. Gajdoš I., Slota J.: Influence of printing conditions on structure in FDM prototypes, Tehnički vjesnik, 20 (2013) 231-236.
6. Lebedev S.M., Gefle O.S., Amitov E.T., Berchuk D.Y., Zhuravlev D.V.: Poly(lactic acid)-based polymer composites with high electric and thermal conductivity and their characterization, Polymer Testing, 58 (2017) 241-248.
7. Farah S., Anderson D.G., Langer R.: Physical and mechanical properties of PLA and their functions in widespread applications – A comprehensive review, Adv. Drug Delivery Rev., 107 (2016) 367-392.
8. Frone A.N., Berlioz S., Chailan J.-F., Panaitescu D.M.: Morphology and thermal properties of PLA-cellulose nanofibers composites, Carbohydrate Polymers, 91 (2013) 377-384.
9. Francil J., Kingery W.D.: Thermal conductivity: IX, Experimental investigation of effect of porosity on thermal conductivity, Mechanical and Thermal Properties of Ceramics Proceedings of Symposium, Gaithersburg, Maryland 1968.
10. Tychanicz M., Smusz R.: Properties, application and thermal investigation of aerogels, ZN PRz, Mechanika, 34 (2017) 95-106.