Mechanical and Physicochemical Properties of 3D-Printed Agave Fibers/Poly(lactic) Acid Biocomposites

Mechanical and Physicochemical Properties of 3D-Printed Agave Fibers/Poly(lactic) Acid Biocomposites

In order to provide a second economic life to agave fibers, an important waste material from the production of tequila, filaments based on polylactic acid (PLA) were filled with agave fibers (0, 3, 5, 10 wt%), and further utilized to produce biocomposites by fused deposition modeling (FDM)-based 3D...

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Main Authors: Valeria Figueroa-Velarde, Tania Diaz-Vidal, Erick Omar Cisneros-López, Jorge Ramón Robledo-Ortiz, Edgar J. López-Naranjo, Pedro Ortega-Gudiño, Luis Carlos Rosales-Rivera
Format: Article
Language:English
Published: MDPI AG 2021-06-01
Series:Materials
Subjects:
agave fibers
3D printing
fused deposition modeling
poly(lactic) acid
biocomposites
Online Access:https://www.mdpi.com/1996-1944/14/11/3111
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spelling doaj-30ba8a5eef92476bbc21355b5b5a116c2021-06-30T23:25:43ZengMDPI AGMaterials1996-19442021-06-01143111311110.3390/ma14113111Mechanical and Physicochemical Properties of 3D-Printed Agave Fibers/Poly(lactic) Acid BiocompositesValeria Figueroa-Velarde0Tania Diaz-Vidal1Erick Omar Cisneros-López2Jorge Ramón Robledo-Ortiz3Edgar J. López-Naranjo4Pedro Ortega-Gudiño5Luis Carlos Rosales-Rivera6University Center of Exact Sciences and Engineering (CUCEI), University of Guadalajara, Guadalajara 44430, MexicoUniversity Center of Exact Sciences and Engineering (CUCEI), University of Guadalajara, Guadalajara 44430, MexicoUniversity Center of Exact Sciences and Engineering (CUCEI), University of Guadalajara, Guadalajara 44430, MexicoUniversity Center of Exact Sciences and Engineering (CUCEI), University of Guadalajara, Guadalajara 44430, MexicoUniversity Center of Exact Sciences and Engineering (CUCEI), University of Guadalajara, Guadalajara 44430, MexicoUniversity Center of Exact Sciences and Engineering (CUCEI), University of Guadalajara, Guadalajara 44430, MexicoUniversity Center of Exact Sciences and Engineering (CUCEI), University of Guadalajara, Guadalajara 44430, MexicoIn order to provide a second economic life to agave fibers, an important waste material from the production of tequila, filaments based on polylactic acid (PLA) were filled with agave fibers (0, 3, 5, 10 wt%), and further utilized to produce biocomposites by fused deposition modeling (FDM)-based 3D printing at two raster angles (−45°/45° and 0°/90°). Differential scanning calorimetry, water uptake, density variation, morphology, and composting of the biocomposites were studied. The mechanical properties of the biocomposites (tensile, flexural, and Charpy impact properties) were determined following ASTM international norms. The addition of agave fibers to the filaments increased the crystallinity value from 23.7 to 44.1%. However, the fibers generated porous structures with a higher content of open cells and lower apparent densities than neat PLA pieces. The printing angle had a low significant effect on flexural and tensile properties, but directly affected the morphology of the printed biocomposites, positively influenced the impact strength, and slightly improved the absorption values for biocomposites printed at −45°/45°. Overall, increasing the concentrations of agave fibers had a detrimental effect on the mechanical properties of the biocomposites. The disintegration of the biocomposites under simulated composting conditions was slowed 1.6-fold with the addition of agave fibers, compared to neat PLA.https://www.mdpi.com/1996-1944/14/11/3111agave fibers3D printingfused deposition modelingpoly(lactic) acidbiocomposites
collection DOAJ
language English
format Article
sources DOAJ
author Valeria Figueroa-Velarde
Tania Diaz-Vidal
Erick Omar Cisneros-López
Jorge Ramón Robledo-Ortiz
Edgar J. López-Naranjo
Pedro Ortega-Gudiño
Luis Carlos Rosales-Rivera
spellingShingle Valeria Figueroa-Velarde
Tania Diaz-Vidal
Erick Omar Cisneros-López
Jorge Ramón Robledo-Ortiz
Edgar J. López-Naranjo
Pedro Ortega-Gudiño
Luis Carlos Rosales-Rivera
Mechanical and Physicochemical Properties of 3D-Printed Agave Fibers/Poly(lactic) Acid Biocomposites
Materials
agave fibers
3D printing
fused deposition modeling
poly(lactic) acid
biocomposites
author_facet Valeria Figueroa-Velarde
Tania Diaz-Vidal
Erick Omar Cisneros-López
Jorge Ramón Robledo-Ortiz
Edgar J. López-Naranjo
Pedro Ortega-Gudiño
Luis Carlos Rosales-Rivera
author_sort Valeria Figueroa-Velarde
title Mechanical and Physicochemical Properties of 3D-Printed Agave Fibers/Poly(lactic) Acid Biocomposites
title_short Mechanical and Physicochemical Properties of 3D-Printed Agave Fibers/Poly(lactic) Acid Biocomposites
title_full Mechanical and Physicochemical Properties of 3D-Printed Agave Fibers/Poly(lactic) Acid Biocomposites
title_fullStr Mechanical and Physicochemical Properties of 3D-Printed Agave Fibers/Poly(lactic) Acid Biocomposites
title_full_unstemmed Mechanical and Physicochemical Properties of 3D-Printed Agave Fibers/Poly(lactic) Acid Biocomposites
title_sort mechanical and physicochemical properties of 3d-printed agave fibers/poly(lactic) acid biocomposites
publisher MDPI AG
series Materials
issn 1996-1944
publishDate 2021-06-01
description In order to provide a second economic life to agave fibers, an important waste material from the production of tequila, filaments based on polylactic acid (PLA) were filled with agave fibers (0, 3, 5, 10 wt%), and further utilized to produce biocomposites by fused deposition modeling (FDM)-based 3D printing at two raster angles (−45°/45° and 0°/90°). Differential scanning calorimetry, water uptake, density variation, morphology, and composting of the biocomposites were studied. The mechanical properties of the biocomposites (tensile, flexural, and Charpy impact properties) were determined following ASTM international norms. The addition of agave fibers to the filaments increased the crystallinity value from 23.7 to 44.1%. However, the fibers generated porous structures with a higher content of open cells and lower apparent densities than neat PLA pieces. The printing angle had a low significant effect on flexural and tensile properties, but directly affected the morphology of the printed biocomposites, positively influenced the impact strength, and slightly improved the absorption values for biocomposites printed at −45°/45°. Overall, increasing the concentrations of agave fibers had a detrimental effect on the mechanical properties of the biocomposites. The disintegration of the biocomposites under simulated composting conditions was slowed 1.6-fold with the addition of agave fibers, compared to neat PLA.
topic agave fibers
3D printing
fused deposition modeling
poly(lactic) acid
biocomposites
url https://www.mdpi.com/1996-1944/14/11/3111
work_keys_str_mv AT valeriafigueroavelarde mechanicalandphysicochemicalpropertiesof3dprintedagavefiberspolylacticacidbiocomposites
AT taniadiazvidal mechanicalandphysicochemicalpropertiesof3dprintedagavefiberspolylacticacidbiocomposites
AT erickomarcisneroslopez mechanicalandphysicochemicalpropertiesof3dprintedagavefiberspolylacticacidbiocomposites
AT jorgeramonrobledoortiz mechanicalandphysicochemicalpropertiesof3dprintedagavefiberspolylacticacidbiocomposites
AT edgarjlopeznaranjo mechanicalandphysicochemicalpropertiesof3dprintedagavefiberspolylacticacidbiocomposites
AT pedroortegagudino mechanicalandphysicochemicalpropertiesof3dprintedagavefiberspolylacticacidbiocomposites
AT luiscarlosrosalesrivera mechanicalandphysicochemicalpropertiesof3dprintedagavefiberspolylacticacidbiocomposites
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